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Identification of components involved in Epsin ubiquitinationBal, Sheila G. 29 October 2012 (has links)
Notch signaling is a major signaling pathway that occurs in many tissues at in nearly all stages of development. In Drosophila, Notch and its ligands, Delta and Serrate, physically interact as a part of activation of the signal. Notch activation requires the endocytic adaptor protein Epsin to facilitate the endocytosis of the ligand Delta. Our laboratory has discovered that Epsin activity is regulated by ubiquitination. Liquid facets, the gene coding for the Drosophila protein related to Epsin, was discovered to be an enhancer of the fat facets (faf) mutant eye phenotype. faf codes for a deubiquitinating enzyme. Epsin has been determined to be a key substrate of the activity of Faf in the eye. An F1 screen for dominant suppressors of the faf phenotype was performed to identify the E3 ubiquitin ligase whose substrate is Epsin. The E2 ubiquitin-conjugating enzyme UbcD1 was isolated as a strong suppressor of the faf mutant eye defect. UbcD1 has previously been identified as a strong suppressor of faf. An RNAi approach was used to study UbcD1’s role in Epsin ubiquitination further. The data that I obtained do not elucidate the UbcD1’s role in Epsin ubiquitination, but instead suggest an alternative role that should be considered. / text
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Determining the role of a small GTPase, Ral, and an endocytic factor, epsin, in Drosophila Notch signalingCho, Bomsoo 08 July 2013 (has links)
Cell-cell communication events are crucial to determine the fate of each cell during development. Notch signaling is involved in many different contexts in determining cell fate by mediating cell-cell communication. Furthermore, regulation of the Notch transduction pathway is critical for normal cellular function, which is implicated in various diseases, including cancers. At a certain developmental time point, intrinsic or extrinsic developmental cues induce biases in ligands and Notch receptors between neighboring cells. These initial biases are further amplified by various cellular factors which eventually dictate cell fates. In Drosophila, two Notch ligands, Delta and Serrate, trigger Notch receptor activation in nearby cells by virtue of numerous regulating factors. One important question in this area is how cells become Notch signal sending or receiving cells for cell fate decisions. I show evidence about a distinct mechanism for biasing the direction of Notch signaling that depends on a small GTPase, Ral, during Drosophila photoreceptor cell development. Investigations described here indicate that Fz signaling up-regulates Ral transcription in a signal sending fate cell, the R3 precursor, and Ral represses ligand-independent activation of Notch in the R3 precursor. This event ensures R3 to become a signaler and contributes to asymmetric Notch activation in the neighboring cell, R4. Ral is a small Ras-like GTPase that regulates membrane trafficking and signaling. Here, possible Ral effector pathways that are important for Notch regulation will be proposed. To trigger Notch activation in adjacent cells, Notch ligand endocytosis by the signaling cells is necessary. Recently, it was suggested that control of membrane trafficking is important not only for ligand signaling, but also for Notch receptor activation. Furthermore, Notch receptor trafficking regulates critical cellular functions, including proliferation, which is implicated in tumors. Therefore, another important question in Notch signaling is about the role of membrane trafficking in regulation of the Notch transduction pathway. Drosophila endocytic epsin, Liquid facets [Lqf], is a key component necessary for ligand endocytosis, thereby triggering Notch activation in adjacent cells. However, its function in signal receiving cells for Notch activation has not been studied. In this dissertation, I provide evidence that epsin is also required in signal receiving cells for Notch activation in developmental contexts. Furthermore, genetic and molecular evidence suggests that epsin regulates Notch receptor trafficking via Rab5-mediated endosomal sorting pathway for Notch activation. These studies support the idea that Notch activation at the plasma membrane is not the only way to transduce Notch signaling, but the Notch receptor must enter through an epsin-mediated endocytic pathway into subcellular compartments to be activated, at least in some contexts. / text
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Function and regulation of Drosophila Epsin in notch signalingXie, Xuanhua 26 January 2012 (has links)
Epsin is an endocytic protein that binds Clathrin, the plasma membrane, Ubiquitin, and also a variety of other endocytic proteins through well-characterized motifs. Although Epsin is a general endocytic factor, genetic analysis in Drosophila and mice revealed that Epsin is essential specifically for internalization of ubiquitinated transmembrane ligands of the Notch receptor, a process required for Notch activation. How Epsin promotes ligand endocytosis and thus Notch signaling is unclear. Here, by generating Drosophila lines containing transgenes that express a variety of different Epsin deletion and substitution variants, I tested each of the five protein or lipid interaction modules of Epsin for a role in Notch activation by each of the two Drosophila ligands, Serrate and Delta. here are five main results of this work that impact present thinking about endocytic machinery/Epsin, Epsin/ligand, or ligand/receptor interactions at the plasma membrane. First, I discovered that deletion or mutation of both UIMs destroys Epsin’s function in Notch signaling and has a greater negative effect on Epsin’s ability to function than removal of any other module type. Second, only one of the two UIMs of Epsin is essential. Third, the lipid-binding function of the ENTH domain is required for maximal Epsin activity. Fourth, although the C-terminal Epsin modules that interact with Clathrin, the adapter protein complex AP-2, or endocytic accessory proteins are necessary collectively for Epsin activity, their functions are highly redundant. Finally, I detected no ligand-specific requirements for Epsin modules. Most unexpected was the finding that Epsin’s Clathrin binding motifs were dispensable. All of these observations are consistent with a model where Epsin’s essential function in ligand cells is to link ubiquitinated Notch ligands to Clathrin-coated vesicles through other Clathrin adapter proteins. / text
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Identification of genes that interact with liquid facetsVan Der Ende, Gerrit Alexander 03 February 2014 (has links)
The protein Liquid facets (Lqf) promotes endocytosis at the plasma membrane1. Lqf activity is required for proper Notch signaling, likely through facilitating the endocytosis of Notch ligand by indirectly linking ligand to clathrin. A genetic modifier screen to identify genes that interact with lqf was performed by a previous graduate student. Genes identified in the screen might provide new insights into how Lqf promotes endocytosis or how Notch signaling is regulated. In this work, I performed genetic mapping techniques to identify the genes mutated in each complementation group of the screen. I identified the gene mutated in complementation group 6 as mitochondrial alanyl tRNA synthetase (Aats-ala-m). tRNA synthetases link a tRNA to its cognate amino acid during translation. Mitochondrial tRNA synthetases function in the mitochondria in translation. Aats-ala-m genetically interacts with lqf, suggesting the two genes function in the same pathway. In this work, I also identified chromosomal regions where the genes mutated in complementation groups 1,2, and 9 are located. / text
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Molecular Details of Membrane Deformation by ENTH DomainsKroppen, Benjamin 22 November 2017 (has links)
No description available.
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The role of auxilin and endocytosis in delta signalingBanks, Susan Marie-Louise 02 July 2012 (has links)
Notch signaling is important for cell-cell signaling during development. Notch signaling is highly conserved across all metazoans and failure in Notch signaling is causative in many human diseases. In the Drosophila eye, activation of the Notch pathway requires Lqf (Drosophila Epsin)-dependent and Clathrin-dependent internalization of the Notch receptor ligands, Delta or Serrate, by the signal-sending cells. However, it is unclear why ligand must be internalized into the signal-sending cells to activate Notch signaling in the signal-receiving cells. Evidence suggests that in addition to Clathrin and Epsin, Auxilin is essential for signaling and is indirectly required for internalization of the Notch receptor ligand Delta. Auxilin functions in uncoating Clathrin-coated vesicles to maintain a pool of free Clathrin and Epsin in the cell. auxilin mutants were used as an entryway to identify previously unknown components of the Notch signaling pathway. An F1, FLP/FRT, EMS screen was performed and enhancers of an auxilin mutant rough eye defect were isolated. The enhancers ultimately formed one complementation group on the 2nd chromosome and fourteen complementation groups on the 3rd chromosome. Three of the 3rd chromosome complementation groups were each identified as Delta, lqf, or hsc70. A single allele was identified as faf. Delta and Epsin have known roles in signaling cells to activate Notch as described above. Hsc70 is an ATPase that functions with Auxilin to uncoat Clathrin-coated vesicles and Faf is a deubiquitinating enzyme that maintains levels of active Epsin in the cell. These results suggest I have isolated mutations in genes closely tied to Notch signaling or functioning directly with Auxilin. Mutations in two genes previously undescribed in Notch signaling in the developing Drosophila eye were also isolated from the screen and identified. The second chromosome complementation group was identified as α-adaptin. α-Adaptin is a subunit of the heterotetrameric Clathrin adaptor protein AP-2. One of the third chromosome complementation groups was identified as crumbs. Crumbs is an integral membrane protein that functions at adherens junctions and in establishing apical/basal polarity in cells. Characterizing roles for α-Adaptin and Crumbs during Notch signaling may elucidate the purpose for Delta internalization to activate Notch signaling. / text
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Prion-like Properties in Vesicle TraffickingMcKeith Pearson II (11205306) 20 August 2023 (has links)
<p>Vesicle trafficking is an important process critical for secretory and endocytic purposes, but it is also crucial for cell homeostasis, <i>e.g.,</i> for maintenance of organelle identity and recycling of membrane components.</p><p>The endomembrane-located adaptor protein Epsin R (Epsin-Related protein) is believed to be important for recycling of SNARES like Vti1b from endosomes to the trans Golgi network (TGN), although its involvement in TGN to endosome transport has been also proposed. Further highlighting its impact in cellular and organismal physiology, certain <i>EPSIN R</i> SNPs have been linked to schizophrenia and Epsin R deficiencies correlate with other pathological conditions related to epidermis homeostasis such as psoriasis and eczema.</p><p>Epsin R belongs to the conserved Epsin family of adaptors and as such it presents a characteristic Epsin N-Terminal Homology (ENTH) domain and a largely unstructured C-terminus. The latter contains binding motifs for important elements of the vesicle trafficking machinery.</p><p>Here we identified a C-terminal region of Epsin R with prion-like characteristics (Prion Forming Region or PFR). We found that GFP-Epsin R is localized in intracellular punctate structures colocalizing with different intracellular markers; however, in contrast to other epsin family members, Epsin R displayed puncta of different size and with different protein content with a substantial contribution of large/bright particles. Importantly, the C-terminal Epsin R’s PFR was required for Epsin R localization and for the formation of large and bright puncta. Further, these structures displayed characteristics shared with other prion-like proteins. Our results therefore suggest that Epsin R possesses PFR-dependent prion properties that play an important role in this adaptor’s localization and function.</p><p>We propose a model in which prion-like proteins like Epsin R can rapidly and stably self-assemble at vesicle budding sites. These proteins would accelerate the formation of vesicle trafficking machinery and the recruitment of cargo. We also speculate that oligomerizing, self-templating reactions would occur under strict control of several cellular factors such as chaperones and post-translational modifications (<i>e.g.,</i> phosphorylation, ubiquitination, etc.) to assure quick and <i>reversible</i> association of prion-like proteins.</p>
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