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Intracellular Survival Mechanisms of Zooxanthellae in Cnidarian Digestive Cells¡XThe Critical Role of ApRab5 and ApRab7Cheng, Ying-Min 21 June 2004 (has links)
Marine cnidarian-microalgal endosymbiosis is an ecologically important intracellular association. However, its underlying molecular mechanisms are essentially unknown. In light of the critical roles of host phagocytosis in intracellular fates of a variety of microbes, and the Rab small GTPases as key mediators of host-symbiont interaction, we set out to investigate the potential involvement of Aiptasia Rab proteins in the model photosynthetic endosymbiosis between the sea anemone, Aiptasia pulchella and the symbiotic dinoflagellate (commonly called zooxanthellae), Symbiodinium spp. Many Aiptasia Rab homologue-encoding cDNA fragments were first cloned through our degenerate RT-PCR and RACE reactions. Significantly, Aiptasia homologues of Rab5 and Rab7 (ApRab5 and ApRab7), two Rabs known to be critical regulators of phagosome maturation were also identified in the screen. The overall sequence identities of ApRab5 and ApRab7 to those of human Rab5C and Rab7 were very extensive, and EGFP reporter, protein fractionation, and immuno-fluorescence studies all suggested that the similarity of the Aiptasia Rabs to their human counterparts extended to the functional levels. Finally, although the phagosomes enclosing latex beads stained positive for ApRab5 and ApRab7 with kinetics characteristics of normal phagosomal maturation, the phagosomes housing zooxanthellae only stained positive for ApRab5. Furthermore, the association of ApRab5 with and the exclusion of ApRab7 from the zooxanthellae-containing phagosomes could be reversed by the heat-killed or photosynthesis-impaired symbionts. Overall, our present study has identified ApRab5 and ApRab7 as potential key regulators of the Aiptasia-Symbiodinium endosymbiosis
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Adenovirus endocytosis and adenoviral gene transfer in cardiovascular and dermatologic disease modelsRauma-Pinola, T. (Tanja) 10 September 2004 (has links)
Abstract
Adenoviral gene transfer is a valuable tool in molecular biology
research. In order to be an efficient and safe vector, adenovirus
structure and infection mechanism as well as molecular biology of the
used transgene need to be well studied. The aim of this study was to
evaluate the role of adenovirus as a gene transfer vector from several
perspectives. Adenovirus uses receptor-mediated endocytosis in order to
enter the target cell. The effect of Rab5 GTPase on adenovirus entry and
gene transfer efficiency was examined first. Next, adenovirus was used
as an investigatory tool in the cardiovascular research, focused on
clarifying the role of adrenomedullin (AM) in heart and vascular
remodeling. Finally, a model of adenoviral gene transfer into skin
fibroblasts was used.
The role of Rab5 GTPase in the adenovirus endocytosis was examined
in HeLa cells using Cy3-labeled adenovirus, and gene transfer efficiency
using β-galactosidase encoding adenovirus. Rab5 increased both
adenovirus uptake and gene transfer, whereas dominant negative Rab5S34N
decreased both endocytosis and gene transfer. The data indicate that
Rab5 is needed in mediating the adenovirus uptake into the target
cell.
In the rat heart, adenovirus-mediated AM gene transfer transiently
improved systolic function both in vivo and
in vitro. AM caused activation of translocation of
protein kinases C ε and δ, whereas phosphorylation of p38
mitogen activated protein kinase was decreased in the left ventricle. AM
significantly attenuated the development of angiotensin II-induced
cardiac hypertrophy. In rats with myocardial infarction, AM enhanced
dilatation of left ventricle and thinning of anterior wall. The role of
AM in neointima formation was evaluated in rat artery after endothelial
injury. Intravascular AM gene transfer decreased neointimal growth and
increased neointimal myofibroblasts apoptosis. These results show that
AM regulates left ventricular systolic function and remodeling in the
heart, and plays a role in pathological vascular remodeling.
Adenovirus-mediated lysyl hydroxylase (LH) gene transfer into skin
fibroblasts of type VI Ehlers-Danlos syndrome patient and rat skin
increased functional LH production, elevated LH activity, and human LH
mRNA production both in vitro and in
vivo. LH gene replacement therapy may thus lead to
possibilities to improve skin wound healing in Ehlers-Danlos syndrome
patients.
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Systems analysis of early endosome motility through identification of molecular motorsChandrashaker, Akhila 04 October 2010 (has links) (PDF)
Endocytosis is an evolutionary conserved process of internalization of cargo from the extracellular environment, be they ligands, nutritional and signaling or pathogens into cells. Following their entry, cargo is received into vesiculo-tubular network of early endosomal compartments from where they are sorted and routed to appropriate cellular destinations through transport along the endocytic network. Recycling cargo is sorted away from other cargo resident in early endosomes through tubulation resulting in fission of recycling vesicles, while those to be degraded are progressively concentrated in early endosomes to be degraded in lysosomes.
Early endosomes are dynamic organelles that have been shown to move centripetally following the internalization of cargo into at the cell periphery. Their motility from the cell periphery to the juxtanuclear location of the cell involves convoluted trajectories that include directed motility, bi-directional switches, saltatory behavior and stalls. This complex motility presumably contributes toward the cargo sorting, duration of cargo residence and spatio-temporal signaling by early endosomes. How the different regimes of motility, and nature and number of molecular motors involved in early endosome motility contribute toward endosome function is not understood.
The aim of this study was to probe into the regulation of endosome motility and understand how transport organizes early endosome network. Towards this end, live cell time-lapse movies of Rab5 endosomes were analyzed to derive motility properties contributing to organization of early endosomes. Consistent and significant bias toward the cell centre (minus end motility) in kinetic parameters such as speed, displacement and duration of motility contribute to centripetal flux of Rab5 early endosomes.
A phenomenological property of early endosome motility is its saltatory behavior that produces saturation curves in Mean Square Displacement (MSD) plots. This phase of motility is descriptive, with no understanding of its mechanism or function. Live cell candidate RNAi screen and cytoskeletal perturbation analysis were performed to identify molecules regulating saltatory motility. To this end, cellular microtubule perturbation and RNAi knock down of several Kinesin motor candidates showed a loss in saturation behavior. Potential candidates identified have to be tested for their effect on endosome function through cargo sorting and kinetic assays to gain insights into the role of saltatory motility in endosome function.
Molecular motors mediate Rab5 motility. Therefore, understanding regulation of motility requires identifying number and nature of molecular motors involved in their transport. Towards this end, a functional cargo (LDL) degradation RNAi screen targeting molecular motors was performed. The Ambion Select technology was used with 3 siRNAs targeting every gene in the library. Analysis of screen produced by lack of phenotype consistency between the multiple siRNAs targeting the same gene. Hence, a search for technology with better target specificity was initiated. Technologies tested were Ambion Select, Ambion Silencer Select, Dharmacon ON-TARGET Plus, esiRNA and Invitrogen Stealth. Invitrogen Stealth technology was found to produce the least off-targets and was most specific in terms of consistency of phenotypes produced by multiple siRNAs silencing the same target gene. Assay conditions were also found to influence the silencing specificities to a significant extent. Hence, a systematic assay optimization exercise was performed in terms of the concentration of siRNA used for transfection and time window of assay to maximize specificity of siRNA silencing. Insights obtained from methodologies developed herein not only provide invaluable guidelines in choosing RNAi commercial libraries for screens, but also underscore the importance of establishing optimal assay conditions to minimize off-targets and improve specificity of silencing target genes.
The motor screen was repeated with RNAi library from Invitrogen Stealth. Several potentially interesting candidates have been identified. Also, correlation analyses of phenotypes produced in the screen have indicated toward potential regulatory motor complexes, all of which await biochemical validation.
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Systems analysis of early endosome motility through identification of molecular motorsChandrashaker, Akhila 06 September 2010 (has links)
Endocytosis is an evolutionary conserved process of internalization of cargo from the extracellular environment, be they ligands, nutritional and signaling or pathogens into cells. Following their entry, cargo is received into vesiculo-tubular network of early endosomal compartments from where they are sorted and routed to appropriate cellular destinations through transport along the endocytic network. Recycling cargo is sorted away from other cargo resident in early endosomes through tubulation resulting in fission of recycling vesicles, while those to be degraded are progressively concentrated in early endosomes to be degraded in lysosomes.
Early endosomes are dynamic organelles that have been shown to move centripetally following the internalization of cargo into at the cell periphery. Their motility from the cell periphery to the juxtanuclear location of the cell involves convoluted trajectories that include directed motility, bi-directional switches, saltatory behavior and stalls. This complex motility presumably contributes toward the cargo sorting, duration of cargo residence and spatio-temporal signaling by early endosomes. How the different regimes of motility, and nature and number of molecular motors involved in early endosome motility contribute toward endosome function is not understood.
The aim of this study was to probe into the regulation of endosome motility and understand how transport organizes early endosome network. Towards this end, live cell time-lapse movies of Rab5 endosomes were analyzed to derive motility properties contributing to organization of early endosomes. Consistent and significant bias toward the cell centre (minus end motility) in kinetic parameters such as speed, displacement and duration of motility contribute to centripetal flux of Rab5 early endosomes.
A phenomenological property of early endosome motility is its saltatory behavior that produces saturation curves in Mean Square Displacement (MSD) plots. This phase of motility is descriptive, with no understanding of its mechanism or function. Live cell candidate RNAi screen and cytoskeletal perturbation analysis were performed to identify molecules regulating saltatory motility. To this end, cellular microtubule perturbation and RNAi knock down of several Kinesin motor candidates showed a loss in saturation behavior. Potential candidates identified have to be tested for their effect on endosome function through cargo sorting and kinetic assays to gain insights into the role of saltatory motility in endosome function.
Molecular motors mediate Rab5 motility. Therefore, understanding regulation of motility requires identifying number and nature of molecular motors involved in their transport. Towards this end, a functional cargo (LDL) degradation RNAi screen targeting molecular motors was performed. The Ambion Select technology was used with 3 siRNAs targeting every gene in the library. Analysis of screen produced by lack of phenotype consistency between the multiple siRNAs targeting the same gene. Hence, a search for technology with better target specificity was initiated. Technologies tested were Ambion Select, Ambion Silencer Select, Dharmacon ON-TARGET Plus, esiRNA and Invitrogen Stealth. Invitrogen Stealth technology was found to produce the least off-targets and was most specific in terms of consistency of phenotypes produced by multiple siRNAs silencing the same target gene. Assay conditions were also found to influence the silencing specificities to a significant extent. Hence, a systematic assay optimization exercise was performed in terms of the concentration of siRNA used for transfection and time window of assay to maximize specificity of siRNA silencing. Insights obtained from methodologies developed herein not only provide invaluable guidelines in choosing RNAi commercial libraries for screens, but also underscore the importance of establishing optimal assay conditions to minimize off-targets and improve specificity of silencing target genes.
The motor screen was repeated with RNAi library from Invitrogen Stealth. Several potentially interesting candidates have been identified. Also, correlation analyses of phenotypes produced in the screen have indicated toward potential regulatory motor complexes, all of which await biochemical validation.
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The regulation of Rab5 by Phosphatidylinositol 3'-Kinase2012 November 1900 (has links)
Rab5 (Ras-related in brain) and Rab4 are small monomeric GTPases that mediate the intracellular trafficking of endocytosed growth factor receptors. Active Rab5-GTP has low intrinsic GTP hydrolysis activity that is stimulated by GTPase activating proteins (GAPs) to make inactive Rab5-GDP. GAPs provide both a catalytic arginine and switch region stabilization functions. The p85 regulatory subunit of phosphatidylinositol 3′-kinase (PI3K) has GAP activity towards Rab5 and Rab4, which is not seen in other PI3Ks. The arginine “finger” residue within p85 is R274. It is unlikely that p85 stabilizes the switch regions of Rab5, which undergo large conformational changes between activation states, because it interacts with both Rab5-GTP and Rab5-GDP. In contrast, the PI3K catalytic subunit p110β binds only Rab5-GTP, suggesting it interacts with the switch regions. Thus, the GAP functions may be provided to Rab5 by the subunits of PI3K acting together, where p85 provides the arginine finger and p110β stabilizes the switch regions. The binding interface of Rab5:p85 was sought using mutations of Rab5 residues not present in the switch regions which were conserved in p85-binding Rab proteins (S84, E106, N113, F145, E172, M175, K179, K180) in GST pull-down experiments with FLAG-p85. The p85 binding site was not resolved with these experiments, suggesting that p85 interaction may involve the contribution of multiple residues of the Rab5 protein. The p110β interaction site on Rab5 was investigated using Rab5 switch region mutants. Pull-down experiments using a stabilized p110 protein construct, where the p85-iSH2 domain was fused to p110 (alpha or beta), were performed. Rab5 mutants I53A, F57A, W74A, Q79L, E80R, Y82A, H83E, L85A, M88A, Y89A and R91E showed reduced p110β binding. All of these residues except E80 and H83 are involved in binding other Rab5 effectors. The Rab5 binding site on p110β was also resolved through mutation of p110β in its Ras binding domain, and includes residues I234, E238 and Y244. This generation of non-binding mutants of both Rab5 and p110β will be invaluable in the characterization of the importance of the p110β:Rab5-GTP interaction for receptor trafficking to endosomes in mammalian cells.
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Modulating Adipogenesis: Key Role of Ras-related Protein Rab5 and its EffectorsHuang, Yongjun 25 June 2018 (has links)
The formation of adipocytes is a complicated process in which insulin and IGF-1 signaling pathways and numerous transcription factors control the conversion of precursor cells to mature fat cells. The Rab5 protein acts as a rate-limiting protein during receptor-mediated endocytosis by switching between a GDP-bound inactive form and a GTP-bound active form. The inactivation and activation of Rab5 are regulated by several Rab5 GTPase activating proteins (GAPs) and Rab5 guanine nucleotide exchange factors (GEFs), respectively.
This dissertation demonstrated that the activity of the small GTPase Rab5 and its regulators are essential for the differentiation of 3T3-L1 pre-adipocytes. Specifically, it showed that Rab5 activation is detrimental to the differentiation process. The overexpression of a dominant-negative Rab5:S34N mutant, but not an active counterpart (Rab5:Q79L), stimulated the differentiation of 3T3-L1 pre-adipocytes. Consequently, the expression of Rab5:S34N increased the expression of two adipogenic-specific transcriptional factors, PPARγ and C/EBPα. siRNA-mediated depletion of Rab5 inhibited the differentiation of 3T3-L1 pre-adipocytes, providing further evidence for the requirement of Rab5 in the process of adipogenesis.
A dramatic decrease of the Rab5-GTP level is also observed during the differentiation of 3T3-L1 pre-adipocytes. Consistent with these observations, I found that the expression of Rab5 GEFs (i.e., RIN1, Rabex-5, and RAP6), which increased the GTP-bound form of Rab5, blocked the differentiation process. In contrast, the expression of Rab5 GAPs (i.e., RN-tre and RabGAP-5), which decreased the GTP-bound form of Rab5, stimulated differentiation of 3T3-L1 pre-adipocytes.
I also found a novel interaction between the VPS9 domain of the Rab5 GEFs and the activated insulin receptor. This interaction is specific since the VPS9 domain did not interact with the catalytic inactive mutant of the insulin receptor and the Rab5 GAPs (no VPS9 domain) did not bind to the activated insulin receptor.
The data point out that a reduction on the GTP-bound form of Rab5 is required for the rapid differentiation of 3T3-L1 pre-adipocytes, identifying Rab5 inactivation as an important contributor of adipogenesis. Also, these observations suggest a novel cellular mechanism of Rab5 activity in the adipogenesis process in connection with the insulin receptor, the Rab5 GAPs, and the Rab5 GEFs.
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The role for the p85 subunit of PI3kinase in the regulation of rab proteinsJanuary 2008 (has links)
Upon activation by the platelet-derived growth factor receptor (PDGFR), phosphatidylinositol 3'-kinase (PI3K) converts phosphatidylinositol 4,5-bisphosphate to phosphatidylinositol 3,4,5-trisphosphate to activate the PI3K/Akt cellular survival signalling pathway within cells. The p85 subunit of PI3K has also been shown to have GTPase activating protein (GAP) activity towards Rab proteins involved in receptor endocytosis and trafficking, specifically Rab5 and Rab4. Rab5 is responsible for regulating the fusion of vesicles containing activated receptors to traffic them to intracellular early/sorting endosomes. Rab4 is responsible for regulating the exit of receptors to a recycling pathway back to the plasma membrane. The p85 RabGAP activity is responsible for deactivating Rab5 and Rab4 function by accelerating their GTPase activity, resulting in the inactive conformation of Rab5 and Rab4, and decreased vesicle fusion events during receptor trafficking. The work in this thesis was performed to understand how p85 interacts with, and regulates, Rab5 and Rab4. Glutathione S-transferase pulldown experiments showed the p85 protein was able to interact with Rab5 through its BH domain and another unidentified domain. Cells expressing a p85-R274A mutant defective for RabGAP activity displayed increased PDGFR activation and decreased degradation. To understand the mechanism of decreased PDGFR degradation, PDGFR immunoprecipitation experiments showed the PDGFR was ubiquitinated, a signal needed for multi-vesicular body sorting. Biotinylation experiments showed the PDGFR was being more rapidly endocytosed and then sequestered within the cell. Immunofluorescence experiments showed cells expressing the p85-R274A mutant clearly altered PDGFR trafficking during receptor endocytosis. These results suggest the PDGFR was not spending longer periods of time on the cell surface to continue signalling and was not lacking the modification needed to be sorted to a degradative pathway. The defective trafficking observed in p85-R274A expressing cells, over time, may block PDGFR trafficking, which prevents normal PDGFR dephosphorylation and degradation, and could be attributed to a lack of sufficient cytosolic Rab5-GDP and Rab4-GDP required to associate with new membranes and facilitate additional vesicle fusion events. The lack of lysosomal targeting allows the receptor to be sequestered in cells, but still have the ability to signal as the receptor would not be targeted to multi-vesicular bodies where signalling is abolished.
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The role for the p85 subunit of PI3kinase in the regulation of rab proteinsKing, Jennifer C 26 January 2009
Upon activation by the platelet-derived growth factor receptor (PDGFR), phosphatidylinositol 3'-kinase (PI3K) converts phosphatidylinositol 4,5-bisphosphate to phosphatidylinositol 3,4,5-trisphosphate to activate the PI3K/Akt cellular survival signalling pathway within cells. The p85 subunit of PI3K has also been shown to have GTPase activating protein (GAP) activity towards Rab proteins involved in receptor endocytosis and trafficking, specifically Rab5 and Rab4. Rab5 is responsible for regulating the fusion of vesicles containing activated receptors to traffic them to intracellular early/sorting endosomes. Rab4 is responsible for regulating the exit of receptors to a recycling pathway back to the plasma membrane. The p85 RabGAP activity is responsible for deactivating Rab5 and Rab4 function by accelerating their GTPase activity, resulting in the inactive conformation of Rab5 and Rab4, and decreased vesicle fusion events during receptor trafficking. The work in this thesis was performed to understand how p85 interacts with, and regulates, Rab5 and Rab4. Glutathione S-transferase pulldown experiments showed the p85 protein was able to interact with Rab5 through its BH domain and another unidentified domain. Cells expressing a p85-R274A mutant defective for RabGAP activity displayed increased PDGFR activation and decreased degradation. To understand the mechanism of decreased PDGFR degradation, PDGFR immunoprecipitation experiments showed the PDGFR was ubiquitinated, a signal needed for multi-vesicular body sorting. Biotinylation experiments showed the PDGFR was being more rapidly endocytosed and then sequestered within the cell. Immunofluorescence experiments showed cells expressing the p85-R274A mutant clearly altered PDGFR trafficking during receptor endocytosis. These results suggest the PDGFR was not spending longer periods of time on the cell surface to continue signalling and was not lacking the modification needed to be sorted to a degradative pathway. The defective trafficking observed in p85-R274A expressing cells, over time, may block PDGFR trafficking, which prevents normal PDGFR dephosphorylation and degradation, and could be attributed to a lack of sufficient cytosolic Rab5-GDP and Rab4-GDP required to associate with new membranes and facilitate additional vesicle fusion events. The lack of lysosomal targeting allows the receptor to be sequestered in cells, but still have the ability to signal as the receptor would not be targeted to multi-vesicular bodies where signalling is abolished.
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Interaction between p85 and Rab5 in the presences and absence of phosphorylated PDGFR peptide2012 January 1900 (has links)
The adaptor subunit of phosphatidylinositol 3'-kinases (PI3K), p85, is involved in many different biological processes. Recent studies have shown that one of these functions is to serve as a GTPase activating protein (GAP) towards Rab5, a small monomeric G-protein. Rab5, like other G-proteins, can bind to either GDP or GTP in vivo, assuming its inactive and active form, respectively. The p85 protein has been shown to associate with both the nucleotide-bound and nucleotide-free states of Rab5. It has also been shown that p85 associates with activated, phosphorylated platelet-derived growth factor receptors (PDGFRs) via its two SH2 domains, and that upon binding there is a conformational change in the p85 protein which leads to a derepression of p110 kinase activity. The purpose of this study was to analyze if binding of the activated PDGFR peptides to p85 affects its Rab5GAP activity, as well as to measure the binding affinity of p85 towards Rab5 in each of its nucleotide-bound states. GAP assays were performed to measure the effect that peptide analogs of both the activated and inactivated PDGFR had on p85 Rab5GAP activity, while the binding affinity of p85 towards Rab5 was measured using surface plasmon resonance. The results of this study suggest that PDGFR peptides have no significant effect on p85 Rab5GAP activity. Furthermore, p85 appears to have a higher magnitude of binding to nucleotide-associated Rab5 proteins, than nucleotide-free Rab5 proteins. It also appears that p85 forms more stable complexes with Rab5-GTP than with Rab5-GDP. These results further support previous studies that show p85 to be an important regulator of Rab5-mediated endosomal fusion and show that this activity is not regulated by binding to the activated PDGFR itself.
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The role for the p85 subunit of PI3kinase in the regulation of rab proteinsKing, Jennifer C 26 January 2009 (has links)
Upon activation by the platelet-derived growth factor receptor (PDGFR), phosphatidylinositol 3'-kinase (PI3K) converts phosphatidylinositol 4,5-bisphosphate to phosphatidylinositol 3,4,5-trisphosphate to activate the PI3K/Akt cellular survival signalling pathway within cells. The p85 subunit of PI3K has also been shown to have GTPase activating protein (GAP) activity towards Rab proteins involved in receptor endocytosis and trafficking, specifically Rab5 and Rab4. Rab5 is responsible for regulating the fusion of vesicles containing activated receptors to traffic them to intracellular early/sorting endosomes. Rab4 is responsible for regulating the exit of receptors to a recycling pathway back to the plasma membrane. The p85 RabGAP activity is responsible for deactivating Rab5 and Rab4 function by accelerating their GTPase activity, resulting in the inactive conformation of Rab5 and Rab4, and decreased vesicle fusion events during receptor trafficking. The work in this thesis was performed to understand how p85 interacts with, and regulates, Rab5 and Rab4. Glutathione S-transferase pulldown experiments showed the p85 protein was able to interact with Rab5 through its BH domain and another unidentified domain. Cells expressing a p85-R274A mutant defective for RabGAP activity displayed increased PDGFR activation and decreased degradation. To understand the mechanism of decreased PDGFR degradation, PDGFR immunoprecipitation experiments showed the PDGFR was ubiquitinated, a signal needed for multi-vesicular body sorting. Biotinylation experiments showed the PDGFR was being more rapidly endocytosed and then sequestered within the cell. Immunofluorescence experiments showed cells expressing the p85-R274A mutant clearly altered PDGFR trafficking during receptor endocytosis. These results suggest the PDGFR was not spending longer periods of time on the cell surface to continue signalling and was not lacking the modification needed to be sorted to a degradative pathway. The defective trafficking observed in p85-R274A expressing cells, over time, may block PDGFR trafficking, which prevents normal PDGFR dephosphorylation and degradation, and could be attributed to a lack of sufficient cytosolic Rab5-GDP and Rab4-GDP required to associate with new membranes and facilitate additional vesicle fusion events. The lack of lysosomal targeting allows the receptor to be sequestered in cells, but still have the ability to signal as the receptor would not be targeted to multi-vesicular bodies where signalling is abolished.
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