Zelluläre Rolle und molekulare Grundlagen des Endosomentransports in Ustilago maydis

Wedlich-Söldner, Roland.

Unknown Date

Universiẗat, Diss., 2001--München.

Charakterisierung der endosomalen Proteintransportfunktion Vps8 der Hefe Saccharomyces cerevisiae

Pawelec, Agnes.

Unknown Date

Universiẗat, Diss., 2005--Düsseldorf.

Untersuchung der Bifunktionalität des endosomalen Proteins Snf7

Huppert, Stefanie.

Unknown Date

Universiẗat, Diss., 2005--Düsseldorf.

The yeast endosomal/TGN-localized Ysl2p-Arl1p-Neo1p network: search for novel interaction partners

Lasić, Maja,

January 2008

Stuttgart, Univ., Diss., 2008.

Rab-domain dynamics in endocytic membrane trafficking

Rink, Jochen.

Unknown Date

Techn. University, Diss., 2005--Dresden.

Early events in cytokine receptor signaling

Gandhi, Hetvi

04 March 2014

Ligand-activated signal transduction is a process critical to cell survival and function as it serves as a means of communication between the cells and their environment. Endocytosis is generally thought to down-regulate incoming signals by reducing the surface availability of receptors. However, increasing evidence in many systems suggests a notion which is referred to as the „signalling endosome" hypothesis - that endocytosis can also actively contribute to signalling apart from clearance of activated receptors and thereby attenuation of signalling. The functional aspect of signalling endosomes has been well-characterized in several pathways including RTK and TGF-β signalling. There are, however, various other signalling pathways where the active mechanism of endocytotic regulation is yet to be understood. In this study, we probe this aspect in the cytokine signalling system, where the receptors are known to internalize but the significance of such internalization and precise mechanism is unclear. My thesis aims to elucidate the function and molecular details of internalization of cytokine receptor using interleukin-4 receptor (IL-4R) signalling as a model. IL-4 and IL-13 ligands can induce assembly of three distinct complexes: IL4 induced IL-4Rα – IL-2Rγ (type I), IL-4 induced IL-4Rα – IL-13Rα1 (type II) or the IL-13 induced IL-13Rα1-IL-4Rα (type II). The formation of any of these complexes triggers signalling through the JAK/STAT pathway. However, models of how the oligomerization of the transmembrane receptors and activation takes place are very diverse and lack a clear molecular and biophysical understanding of the underlying receptor dynamics. Previous results of the lab had shown that the affinities between subunits are low, precluding complex formation at the plasma membrane at physiological concentrations. In addition, IL-4R subunits localize in to endosomal structures adjacent to the plasma membrane. It had already been shown that the shared IL-4R subunit IL-2Rγ is internalized by a specific, actin dependent, Rac1/Pak1 regulated endocytosis route in the IL-2 context. We could show that pharmacological suppression of this endocytosis pathway also prevented IL-4 induced JAK/STAT signalling, placing endocytosis upstream of signalling. Here I show using immuno-EM techniques that these endosomal structures are multivesicular bodies. Importantly, I could show that receptor subunits are highly enriched in the limiting membrane of these endosomes relative to the adjacent plasma membrane. Using quantitative loading assays I could furthermore demonstrate that this enrichment is achieved by constitutive internalization of receptors from the cell surface into cortical endosomes. The trafficking kinetics of the receptor subunits is independent of ligand occupancy. Pharmacological inhibition shows that receptors and ligand traffic via the previously identified Rac1/Pak1 pathway. Finally, Vav2 was identified as a candidate Guanine Exchange Factor (GEF) that may regulate Rac1 activity and thereby control the actin polymerization cascade driving IL-4R endocytosis. Immunoprecipitations showed that Vav2 interacts both with the cytoplasmic tail region of the receptors and the receptor associated 2 kinase JAK3. Vav2 may thus couple the receptor/JAK complexes to the Rac1/Pak1 mediated endocytosis route. Taken together, our results suggests that stable „signalling endosomes‟ adjacent to the plasma membrane act as enrichment centres, where ligand and receptor concentrations are locally increased by constitutive trafficking. The confined environment of the endosome then compensates for the weak affinities between the ligand and receptor and facilitates ligand-mediated receptor dimerization. Importantly, overexpression of both type II IL-4R subunits renders signal transduction resistant to endocytosis inhibition, strongly suggesting that the critical factor effecting signalling is sufficient concentration, which the endosomes facilitate achieving. The endosomes are thus dispensable as signalling scaffolds when the receptors are in sufficient concentration, where activated receptors could interact with downstream pathway components. Endocytosis thus provides a crucial means for the signalling process to overcome the thermodynamic hurdles for receptor oligomerization. In conclusion, our data propose a novel, purely thermodynamic role of endosomes in regulating cytokine receptor signalling not seen in any other signalling pathway.

Zytokinrezeptor

Endosom

JAK-STAT

cytokine receptor

endosome

JAK-STAT

ddc:570

rvk:WE 5200

Functional and structural characterization of a yeast membrane protein involved in the secretory pathway

Votsmeier, Christian.

Unknown Date

Techn. University, Diss., 2002--Berlin.

Early events in cytokine receptor signaling

Gandhi, Hetvi

27 February 2014

Ligand-activated signal transduction is a process critical to cell survival and function as it serves as a means of communication between the cells and their environment. Endocytosis is generally thought to down-regulate incoming signals by reducing the surface availability of receptors. However, increasing evidence in many systems suggests a notion which is referred to as the „signalling endosome" hypothesis - that endocytosis can also actively contribute to signalling apart from clearance of activated receptors and thereby attenuation of signalling. The functional aspect of signalling endosomes has been well-characterized in several pathways including RTK and TGF-β signalling. There are, however, various other signalling pathways where the active mechanism of endocytotic regulation is yet to be understood. In this study, we probe this aspect in the cytokine signalling system, where the receptors are known to internalize but the significance of such internalization and precise mechanism is unclear. My thesis aims to elucidate the function and molecular details of internalization of cytokine receptor using interleukin-4 receptor (IL-4R) signalling as a model. IL-4 and IL-13 ligands can induce assembly of three distinct complexes: IL4 induced IL-4Rα – IL-2Rγ (type I), IL-4 induced IL-4Rα – IL-13Rα1 (type II) or the IL-13 induced IL-13Rα1-IL-4Rα (type II). The formation of any of these complexes triggers signalling through the JAK/STAT pathway. However, models of how the oligomerization of the transmembrane receptors and activation takes place are very diverse and lack a clear molecular and biophysical understanding of the underlying receptor dynamics. Previous results of the lab had shown that the affinities between subunits are low, precluding complex formation at the plasma membrane at physiological concentrations. In addition, IL-4R subunits localize in to endosomal structures adjacent to the plasma membrane. It had already been shown that the shared IL-4R subunit IL-2Rγ is internalized by a specific, actin dependent, Rac1/Pak1 regulated endocytosis route in the IL-2 context. We could show that pharmacological suppression of this endocytosis pathway also prevented IL-4 induced JAK/STAT signalling, placing endocytosis upstream of signalling. Here I show using immuno-EM techniques that these endosomal structures are multivesicular bodies. Importantly, I could show that receptor subunits are highly enriched in the limiting membrane of these endosomes relative to the adjacent plasma membrane. Using quantitative loading assays I could furthermore demonstrate that this enrichment is achieved by constitutive internalization of receptors from the cell surface into cortical endosomes. The trafficking kinetics of the receptor subunits is independent of ligand occupancy. Pharmacological inhibition shows that receptors and ligand traffic via the previously identified Rac1/Pak1 pathway. Finally, Vav2 was identified as a candidate Guanine Exchange Factor (GEF) that may regulate Rac1 activity and thereby control the actin polymerization cascade driving IL-4R endocytosis. Immunoprecipitations showed that Vav2 interacts both with the cytoplasmic tail region of the receptors and the receptor associated 2 kinase JAK3. Vav2 may thus couple the receptor/JAK complexes to the Rac1/Pak1 mediated endocytosis route. Taken together, our results suggests that stable „signalling endosomes‟ adjacent to the plasma membrane act as enrichment centres, where ligand and receptor concentrations are locally increased by constitutive trafficking. The confined environment of the endosome then compensates for the weak affinities between the ligand and receptor and facilitates ligand-mediated receptor dimerization. Importantly, overexpression of both type II IL-4R subunits renders signal transduction resistant to endocytosis inhibition, strongly suggesting that the critical factor effecting signalling is sufficient concentration, which the endosomes facilitate achieving. The endosomes are thus dispensable as signalling scaffolds when the receptors are in sufficient concentration, where activated receptors could interact with downstream pathway components. Endocytosis thus provides a crucial means for the signalling process to overcome the thermodynamic hurdles for receptor oligomerization. In conclusion, our data propose a novel, purely thermodynamic role of endosomes in regulating cytokine receptor signalling not seen in any other signalling pathway.

info:eu-repo/classification/ddc/570

ddc:570

Zytokinrezeptor, Endosom, JAK-STAT

cytokine receptor, endosome, JAK-STAT

Unraveling Phosphatidylinositol 4-kinase function in the yeast Golgi-endosomal system

Demmel, Lars

16 August 2005

In Saccharomyces cerevisiae, experiments with temperature-sensitive mutants of the PI4-kinase Pik1p revealed that the PI4P pool generated by this enzyme is essential for Golgi morphology and normal secretory function and that the PI4P pool at the Golgi represents a regulatory signal on its own. In order to function as a spatial and temporal regulator of membrane traffic, PI4P synthesis and turnover must be tightly regulated. It remains elusive which factors are involved in the targeting and regulation of Pik1p. Little is also known about PI4P binding proteins mediating the effects of this phosphoinositide on Golgi function. Since it has been shown that multiple pathways leave the Golgi towards the plasma membrane one can ask the question whether Pik1p and its product PI4P specifically control one pathway? Here we demonstrate an interaction of Pik1p with the 14-3-3 proteins Bmh1p and Bmh2p. Interestingly, overexpression of Bmh1p and Bmh2p results in multiple genetic interactions with genes involved in late steps of exocytosis and it affects the forward transport of the general amino acid permease Gap1p. The detected interaction depends on the phosphorylation state of Pik1p and Pik1p phosphorylation accompanies its shuttling out of the nucleus into the cytoplasm where presumably the binding to Bmh1/2p occurs. Therefore, we reason that these interactions might serve the sequestration of Pik1p away from the Golgi. This study reveals that Pik1p shows a strong effect on the delivery of Gap1p to the surface whereas the transport of exocytosis markers implicated in the direct Golgi-to-plasma membrane pathway are not significantly disturbed. Cells carrying a deletion of gga2 also show a strong defect in delivery of Gap1p to the surface. In addition, pik1-101 gga2[delta]double mutants display synthetic genetic and membrane transport phenotypes and recruitment of Gga2 to the TGN partially depends on functional Pik1p. Therefore, our results suggest a role of Pik1p in the TGN to endosome pathway.

Bmh1/2

Endosom

Gga2

Golgi

PI4P

Phosphatidylinositol 4-Kinase

Pik1p

Bmh1/2

Gga2

Golgi

Phosphatidylinositol 4-kinase

Pik1p

endosome

ddc:570

rvk:WE 5360

Endosom

Golgi-Apparat

Hefeartige Pilze

Modulation of Cargo Transport and Sorting through Endosome Motility and Positioning

Höpfner, Sebastian

28 October 2005

Utilizing various systems such as cell-based assays but also multicellular organisms such as Drosophila melanogaster and C.elegans, for example, the endocytic system has been shown to consist of a network of biochemically and morphologically distinct organelles that carry out specialized tasks in the uptake, recycling and catabolism of growth factors and nutrients, serving a plethora of key biological functions (Mellman, 1996). Different classes of endosomes were found to exhibit a characteristic intracellular steady state distribution. This distribution pattern observed at steady state results from a dynamic interaction of endosomes with the actin and the microtubule cytoskeleton. It remains unclear, however, which microtubule-based motors besides Dynein control the intracellular distribution and motility of early endosomes and how their function is integrated with the sorting and transport of cargo. The first part of this thesis research outlines the search for such motor. I describe the identification of KIF16B which functions as a novel endocytic motor protein. This molecular motor, a kinesin-3, transports early endosomes to the plus end of microtubules, in a process regulated by the small GTPase Rab5 and its effector, the phosphatidylinositol-3-OH kinase hVPS34. In vivo, KIF16B overexpression relocated early endosomes to the cell periphery and inhibited transport to the degradative pathway. Conversely, expression of dominant-negative mutants or ablation of KIF16B by RNAi caused the clustering of early endosomes to the peri-nuclear region, delayed receptor recycling to the plasma membrane and accelerated degradation. These results suggest that KIF16B, by regulating the plus end motility of early endosomes, modulates the intracellular localization of early endosomes and the balance between receptor recycling and degradation. In displaying Rab5 and PI(3)P-containing cargo selectivity, a remarkable property of KIF16B is that it is subjected to the same regulatory principles governing the membrane tethering and fusion machinery (Zerial and McBride, 2001). Since KIF16B can modulate growth factor degradation, we propose that this motor could have also important implications for signaling. Importantly, KIF16B has provided novel insight into how intracellular localization of endosomes governs the transport activity of these organelles. The second part of this thesis describes the proof-of-principle of a genome-wide screening strategy aimed at gaining insights into the next level of understanding: How the spatial distribution of organelles is linked to their function in an experimental system which features cellular polarity, for example, a tissue or organ. The suitability of C. elegans as a model organism to identify genes functioning in endocytosis has been demonstrated by previous genetic screens (Grant and Hirsh 1999; Fares and Greenwald, 2001). Offering excellent morphological resolution and polarization, the nematode intestine represents a good system to study the apical sorting of a transmembrane marker. The steady state localization of such a marker is likely the result of a dynamic process that depends on biosynthetic trafficking to the apical surface, apical endocytosis and recycling occurring through apical recycling endosomes. Therefore, mis-sorting of this marker upon RNA-mediated interference will be indicative of a failure in one of the aforementioned processes. Furthermore, since it is still largely unclear why apical endosomes maintain their polarized localization, this screen will also monitor the morphology of this endocytic compartment using a second marker. Following image acquisition based on an automated confocal microscope, data can be analyzed using custom-built software allowing objective phenotypic analysis. The successful establishment of the proof-of-principle marks the current state-of-the-art of this large-scale screening project.

Endosom

Mikrotubulus

Motor

Nano

Organelle

Transferrin

Transport

endozytose

kinesin

EGF

Endosome

cargo

endocytosis

kinesin

kinesin-3

motor

nano

transferrin

transport

ddc:570

rvk:WE 5360

Endocytose

Endosom

Intrazellulärer Transport

Kinesin

Mikrotubulus

Molekularer Motor