Global ETD Search

1	An alternative mechanism by which the Notch signal is induced via the endocytic pathway Tongngok, Pajaree January 2011 (has links) The Notch signalling pathway plays an essential role in cell-fate decisions and morphogenesis, and is frequently ectopically activated in human cancers. The signal is initiated through DSL ligand-dependent Notch proteolysis, which releases its intracellular domain. However, over-expression of the E3 ubiquitin ligase Deltex can bypass the requirement for Notch ligands and ectopically activate Notch by directing it into the endocytic pathway. It has been shown that Deltex induced endocytic-Notch signalling, but not DSL-induced signalling, requires both HOPS and AP-3 complex components that mediate trafficking to lysosomes and related organelles. I showed through a combination of the analysis of the dxsm mutant allele and by expression of mutant forms of Deltex in cell culture, that the C-terminal region of Deltex is important for Notch signalling, but is not required for Notch endocytosis. This suggests that the C-terminal region contains an interaction site that may direct endocytosed Notch to the correct endocytic compartment. A key question however was whether this endocytic pathway is utilised for full Notch signaling in normal development alongside the canonical activation mechanism. I therefore investigated the expression of Drosophila midline single-minded (sim), which is a Notch signal reporter gene, and embryonic neurogenesis which is repressed by Notch signalling. I found that deltex, HOPS and AP-3 mutants displayed gaps in sim expression and also a neurogenic phenotype similar to Notch loss-of-function, and consistent with a role for ligand-independent Notch activation in normal development. I found that the penetrance of these phenotypes increased when flies were cultured at higher temperature. These results suggest that Dx/HOPS/AP-3-dependent Notch activation provides a developmental robustness to the Notch signalling network. It was also found that AP-3 and HOPS components have an additional role in regulating cell survival, which is partially separable in time using a temperature shift assay. I also revealed a requirement of maternal Notch for cell survival in early embryonic development, which may be related to the HOPS-dependent function. Comparison of deltex, AP-3 and HOPS mutant phenotypes suggested that there may be functional redundancy of deltex with components that regulate Notch endocytosis, and of AP-3 with proteins that mediate subsequent trafficking to the late endosome/lysosome. Finally I characterised the molecular lesions of an allele of the HOPS component light and the AP-3 component ruby and identified lesions which were consistent with the loss-of-function of these genes. 570
2	Proteomic analysis of the sorting machineries involved in vesicular traffic between the biosynthetic and endosomal compartments / Proteomische Analyse von Sortierungsmaschinerien involviert im vesikulaeren Verkehr zwischen biosynthetischen und endosomalen Kompartimenten Baust, Thorsten Gerhard 06 September 2006 (has links) (PDF) Vesicular traffic along the biosynthetic and endocytic pathways is essential for homeostasis of eukaryotic cells. However, it raised the question of how the proteins characteristic for each compartment are transported to their destination (Bonifacino and Glick, 2004). This study is especially focusing on the connection between the Golgi apparatus and the endosomal compartment, mediated by two parallel trafficking pathways regulated by the clathrin adaptors AP-1A and AP-3 (Owen et al., 2004). Typical cargo molecules sorted along the AP-1A regulated pathway are mannose 6-phosphate receptors (MPRs) (Ghosh et al., 2003) or the gpI envelop glycoprotein of the Vesicular Zoster virus (Alconada et al., 1996), while sorting of lysosomal membrane proteins like Lamp-1 and LimpII is AP-3 regulated (Eskelinen et al., 2003). To study how AP-1A and AP-3 coats are stabilized on membranes and to identify the protein networks involved, a liposome based in vitro assay that recapitulates the fidelity of protein sorting in vivo was developed and combined with proteomic screens. Therefore, liposomes carrying cytoplasmic domains of gpI or Lamp-1/LimpII were used as affinity matrix to recruit selectively AP-1A or AP-3 and associated protein machineries. The coated liposomes were then analyzed by mass spectrometry. Using the in vitro recruitment assay, it was possible to demonstrate that efficient and selective recruitment of AP-1A and AP-3 coats depends on the presence of several low affinity binding sites on membranes. Thus, AP-1A and AP-3 recognize their target membranes by activated Arf1 GTPases, organelle specific phosphoinositides, PI-4P and PI-3P respectively, and distinct cargo molecules carrying intact signals in their cytoplasmic domains. The implication of PI-3P in AP-3 recruitment was further supported by in vivo experiments. During the biochemical characterization of the assay, several lines of evidence indicated that cargo tails containing intact sorting signals stabilize not only AP-1A and AP-3 coats on membranes but also influence the membrane recruitment of Arf1. It is possible that cargo molecules indirectly drive an Arf1 amplification loop, thereby ensuring efficient AP coat assembly. The proteomic screens identified protein networks of ≈40 proteins selectively recruited on AP-1A coated structures. The most appealing result of the analysis was the presence of two additional protein machineries, one involved in actin nucleation the other involved membrane fusion. More precisely, the AP-1A analysis identified the selective recruitment of the AP-1A subunits and interacting molecules (clathrin, g-synergin), Arf1 and Arf1 effectors (Big2, Git1), Rac1 including Rac1 effectors (b-PIX, RhoGEF7) and a Rac1 dependent actin nucleation machinery (Wave/Scar complex, Arp2/3 complex, associated effectors) as well as members of a Rab machinery (Rab11, Rab14). This finding was further supported by in vivo colocalization studies of the AP-1A cargo CI-MPR with CYFIP2, a protein of the Wave/Scar complex, and the localization of Big2 and Git1 on Rab11 positive membranes (Matafora et al., 2001; Shin et al., 2004). The biochemical characterization revealed that the stabilization of AP-1A coats, most probably driven by cargo molecules that stabilize AP-1A and Arf1 on membranes, leads as well to the stabilization of the two other machineries. Thus, the results support the notion that cargo sorting, vesicular movement and membrane fusion are coordinated during early steps of vesicular traffic. In analogy, the proteomic screens on AP-3 coated structures identified as well ≈40 selectively recruited proteins, which constituted a similar supramolecular network of protein machineries involved in coat formation, action nucleation and membrane fusion via Rab proteins. Thus, beside the AP-3 coat including the AP-3 subunits, Arf1 and Arf effectors (Big1, ARAP1, AGAP1), members of the septin family involved in actin rearrangements and most of the already described effectors of Rab5 microdomains (EEA1, Rabaptin-5, Rabex-5, Vps45) involved in early endosomal dynamics were selectively recruited together with Rab5 and Rab7. Thus, the proteomic analysis of AP-1A and AP-3 coated structures suggest that both AP coats use similar principles - coats, actin nucleation devices and Rab fusion machineries - to assemble supramolecular structures needed for membrane traffic. Although we do not have the ultimate proves yet, it seems as AP-1A and AP-3 use different members of subcomplexes, hence different GTPase effectors, different actin nucleation machineries and different Rab GTPases, to regulate their specific transport pathways and to link the different protein machineries. The proteomic analysis revealed for example that they probably use different Arf and Rho GTPase effectors to link the coat with actin nucleation. However, this has to be proven experimentally. In order to understand the networks of protein interactions, bioinformatic tools were used as a first approach. Even though some clues about the overall organization of the supramolecular protein complexes were provided, the direct links to the Rab machinery are still elusive. Maybe the proteins with thus far unknown functions could be involved. The biochemical analysis, especially the role of PIPs, and the Rab GTPases identified in the context of AP-1A and AP-3, provide indications about AP-1A and AP-3 function in vivo. The results could be interpreted in a way that AP-1A functions either in traffic from PI-4P positive membranes towards Rab11/Rab14 positive membranes or AP-1A coats assemble on PI-4P and Rab11 or Rab14 positive membranes, hence, TGN to endosomes traffic. The same holds true for AP-3, the results either suggest AP-3 mediates traffic from PI-3P positive towards Rab5/Rab7 positive membranes or they could be interpreted in a way that AP-3 assembles on PI-3P and Rab5 positive membranes for subsequent transport to Rab7 positive membranes, thus traffic from early to late endosomes. Overall, the results of this thesis research provided important insight into the formation of AP-1A and AP-3 coated structures and the potential interconnection between AP coats, actin nucleation and membrane fusion machineries. Alconada, A., U. Bauer, and B. Hoflack. 1996. A tyrosine-based motif and a casein kinase II phosphorylation site regulate the intracellular trafficking of the varicella-zoster virus glycoprotein I, a protein localized in the trans-Golgi network. Embo J. 15:6096-110. Bonifacino, J.S., and B.S. Glick. 2004. The mechanisms of vesicle budding and fusion. Cell. 116:153-66. Eskelinen, E.L., Y. Tanaka, and P. Saftig. 2003. At the acidic edge: emerging functions for lysosomal membrane proteins. Trends Cell Biol. 13:137-45. Ghosh, P., N.M. Dahms, and S. Kornfeld. 2003. Mannose 6-phosphate receptors: new twists in the tale. Nat Rev Mol Cell Biol. 4:202-12. Matafora, V., S. Paris, S. Dariozzi, and I. de Curtis. 2001. Molecular mechanisms regulating the subcellular localization of p95-APP1 between the endosomal recycling compartment and sites of actin organization at the cell surface. J Cell Sci. 114:4509-20. Owen, D.J., B.M. Collins, and P.R. Evans. 2004. Adaptors for clathrin coats: structure and function. Annu Rev Cell Dev Biol. 20:153-91. Shin, H.W., N. Morinaga, M. Noda, and K. Nakayama. 2004. BIG2, a guanine nucleotide exchange factor for ADP-ribosylation factors: its localization to recycling endosomes and implication in the endosome integrity. Mol Biol Cell. 15:5283-94. membrane traffic AP-1 AP-3 clathrin coated vesicles proteomics Membranverkehr AP-1 AP-3 Clathrinvesikel Proteomics ddc:570 rvk:WD 5275 Membran Adaptorproteine Clathrin Proteomanalyse
3	Proteomic analysis of the sorting machineries involved in vesicular traffic between the biosynthetic and endosomal compartments Baust, Thorsten Gerhard 05 September 2006 (has links) Vesicular traffic along the biosynthetic and endocytic pathways is essential for homeostasis of eukaryotic cells. However, it raised the question of how the proteins characteristic for each compartment are transported to their destination (Bonifacino and Glick, 2004). This study is especially focusing on the connection between the Golgi apparatus and the endosomal compartment, mediated by two parallel trafficking pathways regulated by the clathrin adaptors AP-1A and AP-3 (Owen et al., 2004). Typical cargo molecules sorted along the AP-1A regulated pathway are mannose 6-phosphate receptors (MPRs) (Ghosh et al., 2003) or the gpI envelop glycoprotein of the Vesicular Zoster virus (Alconada et al., 1996), while sorting of lysosomal membrane proteins like Lamp-1 and LimpII is AP-3 regulated (Eskelinen et al., 2003). To study how AP-1A and AP-3 coats are stabilized on membranes and to identify the protein networks involved, a liposome based in vitro assay that recapitulates the fidelity of protein sorting in vivo was developed and combined with proteomic screens. Therefore, liposomes carrying cytoplasmic domains of gpI or Lamp-1/LimpII were used as affinity matrix to recruit selectively AP-1A or AP-3 and associated protein machineries. The coated liposomes were then analyzed by mass spectrometry. Using the in vitro recruitment assay, it was possible to demonstrate that efficient and selective recruitment of AP-1A and AP-3 coats depends on the presence of several low affinity binding sites on membranes. Thus, AP-1A and AP-3 recognize their target membranes by activated Arf1 GTPases, organelle specific phosphoinositides, PI-4P and PI-3P respectively, and distinct cargo molecules carrying intact signals in their cytoplasmic domains. The implication of PI-3P in AP-3 recruitment was further supported by in vivo experiments. During the biochemical characterization of the assay, several lines of evidence indicated that cargo tails containing intact sorting signals stabilize not only AP-1A and AP-3 coats on membranes but also influence the membrane recruitment of Arf1. It is possible that cargo molecules indirectly drive an Arf1 amplification loop, thereby ensuring efficient AP coat assembly. The proteomic screens identified protein networks of ≈40 proteins selectively recruited on AP-1A coated structures. The most appealing result of the analysis was the presence of two additional protein machineries, one involved in actin nucleation the other involved membrane fusion. More precisely, the AP-1A analysis identified the selective recruitment of the AP-1A subunits and interacting molecules (clathrin, g-synergin), Arf1 and Arf1 effectors (Big2, Git1), Rac1 including Rac1 effectors (b-PIX, RhoGEF7) and a Rac1 dependent actin nucleation machinery (Wave/Scar complex, Arp2/3 complex, associated effectors) as well as members of a Rab machinery (Rab11, Rab14). This finding was further supported by in vivo colocalization studies of the AP-1A cargo CI-MPR with CYFIP2, a protein of the Wave/Scar complex, and the localization of Big2 and Git1 on Rab11 positive membranes (Matafora et al., 2001; Shin et al., 2004). The biochemical characterization revealed that the stabilization of AP-1A coats, most probably driven by cargo molecules that stabilize AP-1A and Arf1 on membranes, leads as well to the stabilization of the two other machineries. Thus, the results support the notion that cargo sorting, vesicular movement and membrane fusion are coordinated during early steps of vesicular traffic. In analogy, the proteomic screens on AP-3 coated structures identified as well ≈40 selectively recruited proteins, which constituted a similar supramolecular network of protein machineries involved in coat formation, action nucleation and membrane fusion via Rab proteins. Thus, beside the AP-3 coat including the AP-3 subunits, Arf1 and Arf effectors (Big1, ARAP1, AGAP1), members of the septin family involved in actin rearrangements and most of the already described effectors of Rab5 microdomains (EEA1, Rabaptin-5, Rabex-5, Vps45) involved in early endosomal dynamics were selectively recruited together with Rab5 and Rab7. Thus, the proteomic analysis of AP-1A and AP-3 coated structures suggest that both AP coats use similar principles - coats, actin nucleation devices and Rab fusion machineries - to assemble supramolecular structures needed for membrane traffic. Although we do not have the ultimate proves yet, it seems as AP-1A and AP-3 use different members of subcomplexes, hence different GTPase effectors, different actin nucleation machineries and different Rab GTPases, to regulate their specific transport pathways and to link the different protein machineries. The proteomic analysis revealed for example that they probably use different Arf and Rho GTPase effectors to link the coat with actin nucleation. However, this has to be proven experimentally. In order to understand the networks of protein interactions, bioinformatic tools were used as a first approach. Even though some clues about the overall organization of the supramolecular protein complexes were provided, the direct links to the Rab machinery are still elusive. Maybe the proteins with thus far unknown functions could be involved. The biochemical analysis, especially the role of PIPs, and the Rab GTPases identified in the context of AP-1A and AP-3, provide indications about AP-1A and AP-3 function in vivo. The results could be interpreted in a way that AP-1A functions either in traffic from PI-4P positive membranes towards Rab11/Rab14 positive membranes or AP-1A coats assemble on PI-4P and Rab11 or Rab14 positive membranes, hence, TGN to endosomes traffic. The same holds true for AP-3, the results either suggest AP-3 mediates traffic from PI-3P positive towards Rab5/Rab7 positive membranes or they could be interpreted in a way that AP-3 assembles on PI-3P and Rab5 positive membranes for subsequent transport to Rab7 positive membranes, thus traffic from early to late endosomes. Overall, the results of this thesis research provided important insight into the formation of AP-1A and AP-3 coated structures and the potential interconnection between AP coats, actin nucleation and membrane fusion machineries. Alconada, A., U. Bauer, and B. Hoflack. 1996. A tyrosine-based motif and a casein kinase II phosphorylation site regulate the intracellular trafficking of the varicella-zoster virus glycoprotein I, a protein localized in the trans-Golgi network. Embo J. 15:6096-110. Bonifacino, J.S., and B.S. Glick. 2004. The mechanisms of vesicle budding and fusion. Cell. 116:153-66. Eskelinen, E.L., Y. Tanaka, and P. Saftig. 2003. At the acidic edge: emerging functions for lysosomal membrane proteins. Trends Cell Biol. 13:137-45. Ghosh, P., N.M. Dahms, and S. Kornfeld. 2003. Mannose 6-phosphate receptors: new twists in the tale. Nat Rev Mol Cell Biol. 4:202-12. Matafora, V., S. Paris, S. Dariozzi, and I. de Curtis. 2001. Molecular mechanisms regulating the subcellular localization of p95-APP1 between the endosomal recycling compartment and sites of actin organization at the cell surface. J Cell Sci. 114:4509-20. Owen, D.J., B.M. Collins, and P.R. Evans. 2004. Adaptors for clathrin coats: structure and function. Annu Rev Cell Dev Biol. 20:153-91. Shin, H.W., N. Morinaga, M. Noda, and K. Nakayama. 2004. BIG2, a guanine nucleotide exchange factor for ADP-ribosylation factors: its localization to recycling endosomes and implication in the endosome integrity. Mol Biol Cell. 15:5283-94. info:eu-repo/classification/ddc/570 ddc:570
4	Targeting of the yeast Sna3p and Sna4p to the endosomal pathway depends on their interaction with ubiquitin ligase Rsp5p Pokrzywa, Wojciech 12 March 2009 (has links) Sna3p and Sna4p are small proteins of unknown function possessing two transmembrane domains and belong to a small family of conserved proteins present in plant and fungi. The budding yeast has four SNA proteins (Sna1–4) that have different localizations in the cell. Sna3p is targeted to the vacuolar lumen by the multivesicular body pathway. Two observations marked Sna3p as a multivesicular body cargo that is sorted in an ubiquitin-independent manner. First, Sna3p-GFP is still correctly transported to internal multivesicular body vesicles under conditions of ubiquitin depletion, which impairs multivesicular body sorting of certain other cargoes. Second, a mutant form of Sna3p-GFP lacking the only potential positions for ubiquitylation is still correctly targeted to the vacuolar lumen. It has thus been postulated that ubiquitylation marks, but not all, membrane proteins for sorting into the interior of the vacuole. In this study we present a further characterization of the Golgi to vacuole trafficking of Sna3p together with its ubiquitylation status. We observed that Sna3p physically interacts with the E3 ligase Rsp5p and that this interaction is essential for sorting of Sna3p to the endosomal pathway. Sna3p is ubiquitylated on its Lys125 residue by Rsp5p and modified by Lys 63-linked ubiquitin chains. In contrast to the conclusions from prior reports, we demonstrated that, as noticed for most other multivesicular body cargoes, Sna3p ubiquitylation is required for its multivesicular body sorting. Sna4p is localized to the vacuolar membrane and interior. Sna4p contains an acidic di-leucine motif, that could be a sorting signal specific for AP-3 dependent pathway directing Sna4p to the vacuolar membrane. In apm3∆ cells, where µ subunit of the AP-3 complex is deleted, Sna4p is missorted to the vacuolar interior. Strikingly, this localization is different from localization of markers of AP-3 dependent pathway. This dissimilarity indicates that Sna4p possesses an additional characteristic, absent in other AP-3 cargoes, driving it to the vacuolar interior. In this study we have shown that the acidic di-leucine motif is indeed the sorting signal of Sna4p to the vacuolar membrane through the AP-3 dependent pathway, and that a part of Sna4p is targeted to the vacuole lumen via the multivesicular body pathway. The ability to enter multivesicular bodies is linked to the c-terminal PPPY sequence of Sna4p. Sna4p interacts with Rsp5p via this PY motif, resulting in Sna4p ubiquitylation on its lysine 128 and incorporation into the multivesicular bodies. Thus, Sna4p possesses two functional sorting signals which allow it to use two different pathways directing the protein to the vacuole. Rsp5p Ubiquitin ligase Ubiquitin Sna3p Sna4p Multivesicular body AP-3 adaptor
5	Characterisation of the AP-3 adaptor-like complex Peden, Andrew Alexander January 2000 (has links) Clathrin coated vesicles were the first type of coated vesicle to be characterised. The coat consists of two components, clathrin and adaptor (or AP) complexes, the AP-1 complex is associated with the clathrin coated vesicles that bud from the TGN and the AP-2 complex is associated with the clathrin coated vesicles that bud from the plasma membrane. A new type of adaptor-like complex was discovered in our laboratory and was published in 1996. The complex has been shown to consist of two known proteins, beta3B and mu3B, and two unknown proteins of 160kD and 22kD. Unlike the conventional adaptor complexes this complex is not associated with clathrin. The aim of this thesis was to complete the characterisation of the adaptor-like complex and to establish its function. My studies have shown that, the adaptor-like complex consist of an alpha/gamma like subunit, delta, a beta subunit (beta3A/B), a mu subunit (mu3A/B) and a sigma subunit (sigma3A/B). We named the adaptor-like complexAP-3, by analogy with the AP-1 and AP-2 complexes. The AP-3 complex is localised to perinuclear and more peripheral membranes in non-neuronal cells, with little overlap with endocytic markers. The beta subunit of the AP-3 complex is the major target for phosphorylation. Analysis of mice with mutations in the beta3A subunit, and in the delta subunit of the AP-3 complex, have revealed that the beta subunit is required for the stability of the mu subunit and that the delta subunit is essential for the stability of the whole complex. Further analysis of the mutant mice indicated that the mice lack significant levels of functional AP-3 complex. Studies on fibroblasts generated from these mice revealed that the AP-3 complex plays a role in the trafficking of LAMPI to lysosomes. 572
6	Analyse der putativen AP-3-Funktion für die Vesikelbildung am Trans-Golgi-Netzwerk. / Analysis of the putative AP-3 fuction for vesicle formation at the transgolgi network. Chapuy, Björn 17 January 2006 (has links) No description available. 610 Medizin, Gesundheit Medicine AP-1 AP-3 Tyrosinase MPR46 Lamp-1 TRP-1 Sorting Trans-Golgi-Netzwerk Budding-Assay Vesikulärer Transport AP-1 AP-3 tyrosinase MPR46 Lamp-1 TRP-1 sorting trans golgi network budding assay vesicular transport
7	Protein-Protein-Wechselwirkungen bei der AP-3-Vesikelbildung und –fusion und der Protonenleitung durch die ATP-Synthase Langemeyer, Lars 09 July 2010 (has links) Zu den Eigenschaften eukaryotischer Zellen gehört ihre Kompartimentierung, welche durch die Abtrennung verschiedener Reaktionsräume durch Lipiddoppelschichten erreicht wird. Verschiedene Vesikel-Transportwege verbinden diese Kompartimente miteinander, einer dieser Wege in der Hefe Saccharomyces cerevisiae ist der sogenannte ALP-Weg. Dieser gehört zu den biosynthetischen Wegen, über die neue Proteine an ihren Bestimmungsort gebracht werden, in diesem Falle die Vakuole. Ausgehend vom Golgi-Apparat werden die Vesikel dieses Weges mit Hilfe des Adaptorproteinkomplexes-3 (AP-3) gebildet. Ein weiteres Protein, das eine spezifische Funktion in diesem Weg übernimmt, ist Vps41. Ein aktuelles Modell beschreibt seine Funktion in der Aufnahme der Vesikel an der Vakuole. Es konnte gezeigt werden, das Vps41 mit der sogenannten ear-Domäne von Apl5, einer Untereinheit des AP-3- Komplexes, interagiert. In dieser Arbeit konnte ich nachweisen, dass die Interaktionsstelle im Vps41 innerhalb einer konservierten PEST-Domäne liegt. Eine Deletion dieser Domäne beeinflußte die Funktion des Proteins im ALP-Weg jedoch nicht die in der homotypischen Vakuolenfusion und im CPY-Weg. Eine weitere Eingrenzung des deletierten Bereiches zeigte, dass die PEST-Domäne eine Sequenz enthält, die einem Di-Leucin- Sortierungssignal ähnlich ist. Dieses konnte ich als minimal notwendigen Bereich für die Wechselwirkung mit der Apl5-ear-Domäne bestimmen. Meine Daten zeigen, dass dieser Bereich des Proteins notwendig ist für das Docking der AP-3-Vesikel an der Vakuole. Weiterhin konnte ich eine kompetitive Bindung von Liposomen und Apl5 an die N-terminale Hälfte von Vps41 zeigen. Zusammengefasst und mit aktuellen Veröffentlichungen in Zusammhang gebracht, ergänzen meine Daten das Modell der Funktion von Vps41 in der Vesikelaufnahme an der Vakuole: Vps41 wird durch die Rab-GTPase Ypt7, als deren Effektorprotein, an späte Endosomen gebunden. An dieser stark gekrümmten Membran taucht ein kürzlich identifiziertes ALPS (amphipathic lipid packing sensor)-Motiv im Vps41 in die Membran des Organells ein und zieht so den N-terminalen Bereich mit der Bindestelle für die AP-3-Vesikel an die Oberfläche des Organells wodurch eine verfrühte Fusion der AP-3-Vesikel mit dem Endosom verhindert wird. Erst nach der Reifung zur Vakuole wird die PEST-Domäne für die Bindung an Apl5 verfügbar, da sich die Membrankrümmung ändert. Zusätzlich wird das ALPS-Motiv phosphoryliert, so dass dieses nicht mehr in die Membran eintauchen kann. Erst jetzt ist eine Interaktion zwischen Apl5 und Vps41 und damit eine Fusion der AP-3-Vesikel mit der Vakuole möglich. Der zweite Teil dieser Arbeit beschäftigt sich mit der Protonentranslokation durch den Fo-Teil der ATP-Synthase aus Escherichia coli. Durch Mutagenese wurden ATP-Synthasen hergestellt, in denen die beiden für den Protonentransport essentiellen Aminosäurereste D61 in der Untereinheit c und R210 in der Untereinheit a in der α-Helix in der sie liegen, entweder einzeln oder beide zusammen, um je eine Helixwindung nach oben oder unten verschoben wurden. Dies führt zu einer Verlängerung bzw. Verkürzung der Protonenzu- und austrittskanäle. Durch die Untersuchung der Funktionalität dieser ATPasen auf sowohl aktives und passives Protonenpumpen, als auch ATP-Synthese konnte ich zeigen, daß die Position der beiden essentiellen Aminosäurereste cD61 und aR210 zueinander nicht entscheidend ist. Werden beide Reste in die gleiche Richtung verschoben, so daß ihre Position zueinander gleich bleibt, kommt es unabhängig von der Richtung immer zu einem kompletten Funktionsverlust. Weiterhin läßt sich aus meinen Daten folgern, daß die Position des Restes aR210 in der Mitte der Membran wichtig ist. Beim Verschieben des Restes auf die Position 206 (a-up) geht die gesamte Funktion des Fo-Teiles verloren, während das Verschieben auf die Position 214 (a-down) zu einem passiven Ausströmen der Protonen durch den Fo-Teil führt. Die Position des Restes cD61 in der Membran ist flexibler. Obwohl die Repositionierung des Aspartats auf die Position 57 (c-up) jegliche Funktionalität des Fo-Teiles beeinträchtigt, ermöglicht ein Verschieben auf die Position 65 (c-down) aktives und passives Protonenpumpen, sowie die Synthese von ATP. FoF1-ATPase ATP-Synthase AP-3 ALP-Weg Vps41 Fo-Teil 42.15 - Zellbiologie 42.12 - Biophysik ddc:570 ddc:500
8	O envolvimento da proteína adaptadora 1 (AP-1) no mecanismo de regulação negativa do receptor CD4 por Nef de HIV-1 / The involvement of Adaptor Protein 1 (AP-1) on the Mechanism of CD4 Down-regulation by Nef from HIV-1 Tavares, Lucas Alves 05 August 2016 (has links) O Vírus da Imunodeficiência Humana (HIV) é o agente etiológico da Síndrome da Imunodeficiência Adquirida (AIDS). A AIDS é uma doença de distribuição mundial, e estima-se que existam atualmente pelo menos 36,9 milhões de pessoas infectadas com o vírus. Durante o seu ciclo replicativo, o HIV promove diversas alterações na fisiologia da célula hospedeira a fim de promover sua sobrevivência e potencializar a replicação. A rápida progressão da infecção pelo HIV-1 em humanos e em modelos animais está intimamente ligada à função da proteína acessória Nef. Dentre as diversas ações de Nef está a regulação negativa de proteínas importantes na resposta imunológica, como o receptor CD4. Sabe-se que esta ação resulta da indução da degradação de CD4 em lisossomos, mas os mecanismos moleculares envolvidos ainda são totalmente elucidados. Nef forma um complexo tripartite com a cauda citosólica de CD4 e a proteína adaptadora 2 (AP-2), em vesículas revestidas por clatrina nascentes, induzindo a internalização e degradação lisossomal de CD4. Pesquisas anteriores demonstraram que o direcionamento de CD4 aos lisossomos por Nef envolve a entrada do receptor na via dos corpos multivesiculares (MVBs), por um mecanismo atípico, pois, embora não necessite da ubiquitinação de carga, depende da ação de proteínas que compõem os ESCRTs (Endosomal Sorting Complexes Required for Transport) e da ação de Alix, uma proteína acessória da maquinaria ESCRT. Já foi reportado que Nef interage com subunidades dos complexos AP-1, AP-2, AP-3 e Nef não parece interagir com subunidades de AP-4 e AP-5. Entretanto, o papel da interação de Nef com AP-1 e AP-3 na regulação negativa de CD4 ainda não está totalmente elucidado. Ademais, AP-1, AP-2 e AP-3 são potencialmente heterogêneos devido à existência de isoformas múltiplas das subunidades codificadas por diferentes genes. Todavia, existem poucos estudos para demonstrar se as diferentes combinações de isoformas dos APs são formadas e se possuem propriedades funcionais distintas. O presente trabalho procurou identificar e caracterizar fatores celulares envolvidos na regulação do tráfego intracelular de proteínas no processo de regulação negativa de CD4 induzido por Nef. Mais especificamente, este estudo buscou caracterizar a participação do complexo AP-1 na modulação negativa de CD4 por Nef de HIV-1, através do estudo funcional das duas isoformas de ?-adaptina, subunidades de AP-1. Utilizando a técnica de Pull-down demonstramos que Nef é capaz de interagir com ?2. Além disso, nossos dados de Imunoblot indicaram que a proteína ?2-adaptina, e não ?1-adaptina, é necessária no processo de degradação lisossomal de CD4 por Nef e que esta participação é conservada para degradação de CD4 por Nef de diferentes cepas virais. Ademais, por citometria de fluxo, o silenciamento de ?2, e não de ?1, compromete a diminuição dos níveis de CD4 por Nef da membrana plasmática. A análise por imunofluorêsncia indireta também revelou que a diminuição dos níveis de ?2 impede a redistribuição de CD4 por Nef para regiões perinucleares, acarretando no acúmulo de CD4, retirados por Nef da membrana plasmática, em endossomos primários. A depleção de ?1A, outra subunidade de AP-1, acarretou na diminuição dos níveis celulares de ?2 e ?1, bem como, no comprometimento da eficiente degradação de CD4 por Nef. Além disso, foi possível observar que, ao perturbar a maquinaria ESCRT via super-expressão de HRS (uma subunidade do complexo ESCRT-0), ocorreu um acumulo de ?2 em endossomos dilatados contendo HRS-GFP, nos quais também detectou-se CD4 que foi internalizado por Nef. Em conjunto, os resultados indicam que ?2-adaptina é uma importante molécula para o direcionamento de CD4 por Nef para a via ESCRT/MVB, mostrando ser uma proteína relevante no sistema endo-lisossomal. Ademais, os resultados indicaram que as isoformas ?-adaptinas não só possuem funções distintas, mas também parecem compor complexos AP-1 com diferentes funções celulares, já que apenas a variante AP-1 contendo ?2, mas não ?1, participa da regulação negativa de CD4 por Nef. Estes estudos contribuem para o melhor entendimento dos mecanismos moleculares envolvidos na atividade de Nef, que poderão também ajudar na melhor compreensão da patogênese do HIV e da síndrome relacionada. Em adição, este trabalho contribui para o entendimento de processos fundamentais da regulação do tráfego de proteínas transmembrana no sistema endo-lisossomal. / The Human Immunodeficiency Virus (HIV) is the etiologic agent of Acquired Immunodeficiency Syndrome (AIDS). AIDS is a disease which has a global distribution, and it is estimated that there are currently at least 36.9 million people infected with the virus. During the replication cycle, HIV promotes several changes in the physiology of the host cell to promote their survival and enhance replication. The fast progression of HIV-1 in humans and animal models is closely linked to the function of an accessory protein Nef. Among several actions of Nef, one is the most important is the down-regulation of proteins from the immune response, such as the CD4 receptor. It is known that this action causes CD4 degradation in lysosome, but the molecular mechanisms are still incompletely understood. Nef forms a tripartite complex with the cytosolic tail of the CD4 and adapter protein 2 (AP-2) in clathrin-coated vesicles, inducing CD4 internalization and lysosome degradation. Previous research has demonstrated that CD4 target to lysosomes by Nef involves targeting of this receptor to multivesicular bodies (MVBs) pathway by an atypical mechanism because, although not need charging ubiquitination, depends on the proteins from ESCRTs (Endosomal Sorting Complexes Required for Transport) machinery and the action of Alix, an accessory protein ESCRT machinery. It has been reported that Nef interacts with subunits of AP- 1, AP-2, AP-3 complexes and Nef does not appear to interact with AP-4 and AP-5 subunits. However, the role of Nef interaction with AP-1 or AP-3 in CD4 down-regulation is poorly understood. Furthermore, AP-1, AP-2 and AP-3 are potentially heterogeneous due to the existence of multiple subunits isoforms encoded by different genes. However, there are few studies to demonstrate if the different combinations of APs isoforms are form and if they have distinct functional properties. This study aim to identify and characterize cellular factors involved on CD4 down-modulation induced by Nef from HIV-1. More specifically, this study aimed to characterize the involvement of AP-1 complex in the down-regulation of CD4 by Nef HIV-1 through the functional study of the two isoforms of ?-adaptins, AP-1 subunits. By pull-down technique, we showed that Nef is able to interact with ?2. In addition, our data from immunoblots indicated that ?2- adaptin, not ?1-adaptin, is required in Nef-mediated targeting of CD4 to lysosomes and the ?2 participation in this process is conserved by Nef from different viral strains. Furthermore, by flow cytometry assay, ?2 depletion, but not ?1 depletion, compromises the reduction of surface CD4 levels induced by Nef. Immunofluorescence microscopy analysis also revealed that ?2 depletion impairs the redistribution of CD4 by Nef to juxtanuclear region, resulting in CD4 accumulation in primary endosomes. Knockdown of ?1A, another subunit of AP-1, resulted in decreased cellular levels of ?1 and ?2 and, compromising the efficient CD4 degradation by Nef. Moreover, upon artificially stabilizing ESCRT-I in early endosomes, via overexpression of HRS, internalized CD4 accumulates in enlarged HRS-GFP positive endosomes, where co-localize with ?2. Together, the results indicate that ?2-adaptin is a molecule that is essential for CD4 targeting by Nef to ESCRT/MVB pathway, being an important protein in the endo-lysosomal system. Furthermore, the results indicate that ?-adaptins isoforms not only have different functions, but also seem to compose AP-1 complex with distinct cell functions, and only the AP-1 variant comprising ?2, but not ?1, acts in the CD4 down-regulation induced by Nef. These studies contribute to a better understanding on the molecular mechanisms involved in Nef activities, which may also help to improve the understanding of the HIV pathogenesis and the related syndrome. In addition, this work contributes with the understanding of primordial process regulation on intracellular trafficking of transmembrane proteins. ?2 depletion and only the AP-1 variant comprising ?2 another subunit of AP-1 AP-1 AP-1 AP-1 subunits. By pull-down technique AP-2 but not ?1 but not ?1 depletion by flow cytometry assay ESCRT HIV-1 MVB Nef not ?1-adaptin regulação negativa de CD4 via overexpression of HRS where co-localize with ?2. Together y1-adaptina y2-adaptina
9	O envolvimento da proteína adaptadora 1 (AP-1) no mecanismo de regulação negativa do receptor CD4 por Nef de HIV-1 / The involvement of Adaptor Protein 1 (AP-1) on the Mechanism of CD4 Down-regulation by Nef from HIV-1 Lucas Alves Tavares 05 August 2016 (has links) O Vírus da Imunodeficiência Humana (HIV) é o agente etiológico da Síndrome da Imunodeficiência Adquirida (AIDS). A AIDS é uma doença de distribuição mundial, e estima-se que existam atualmente pelo menos 36,9 milhões de pessoas infectadas com o vírus. Durante o seu ciclo replicativo, o HIV promove diversas alterações na fisiologia da célula hospedeira a fim de promover sua sobrevivência e potencializar a replicação. A rápida progressão da infecção pelo HIV-1 em humanos e em modelos animais está intimamente ligada à função da proteína acessória Nef. Dentre as diversas ações de Nef está a regulação negativa de proteínas importantes na resposta imunológica, como o receptor CD4. Sabe-se que esta ação resulta da indução da degradação de CD4 em lisossomos, mas os mecanismos moleculares envolvidos ainda são totalmente elucidados. Nef forma um complexo tripartite com a cauda citosólica de CD4 e a proteína adaptadora 2 (AP-2), em vesículas revestidas por clatrina nascentes, induzindo a internalização e degradação lisossomal de CD4. Pesquisas anteriores demonstraram que o direcionamento de CD4 aos lisossomos por Nef envolve a entrada do receptor na via dos corpos multivesiculares (MVBs), por um mecanismo atípico, pois, embora não necessite da ubiquitinação de carga, depende da ação de proteínas que compõem os ESCRTs (Endosomal Sorting Complexes Required for Transport) e da ação de Alix, uma proteína acessória da maquinaria ESCRT. Já foi reportado que Nef interage com subunidades dos complexos AP-1, AP-2, AP-3 e Nef não parece interagir com subunidades de AP-4 e AP-5. Entretanto, o papel da interação de Nef com AP-1 e AP-3 na regulação negativa de CD4 ainda não está totalmente elucidado. Ademais, AP-1, AP-2 e AP-3 são potencialmente heterogêneos devido à existência de isoformas múltiplas das subunidades codificadas por diferentes genes. Todavia, existem poucos estudos para demonstrar se as diferentes combinações de isoformas dos APs são formadas e se possuem propriedades funcionais distintas. O presente trabalho procurou identificar e caracterizar fatores celulares envolvidos na regulação do tráfego intracelular de proteínas no processo de regulação negativa de CD4 induzido por Nef. Mais especificamente, este estudo buscou caracterizar a participação do complexo AP-1 na modulação negativa de CD4 por Nef de HIV-1, através do estudo funcional das duas isoformas de ?-adaptina, subunidades de AP-1. Utilizando a técnica de Pull-down demonstramos que Nef é capaz de interagir com ?2. Além disso, nossos dados de Imunoblot indicaram que a proteína ?2-adaptina, e não ?1-adaptina, é necessária no processo de degradação lisossomal de CD4 por Nef e que esta participação é conservada para degradação de CD4 por Nef de diferentes cepas virais. Ademais, por citometria de fluxo, o silenciamento de ?2, e não de ?1, compromete a diminuição dos níveis de CD4 por Nef da membrana plasmática. A análise por imunofluorêsncia indireta também revelou que a diminuição dos níveis de ?2 impede a redistribuição de CD4 por Nef para regiões perinucleares, acarretando no acúmulo de CD4, retirados por Nef da membrana plasmática, em endossomos primários. A depleção de ?1A, outra subunidade de AP-1, acarretou na diminuição dos níveis celulares de ?2 e ?1, bem como, no comprometimento da eficiente degradação de CD4 por Nef. Além disso, foi possível observar que, ao perturbar a maquinaria ESCRT via super-expressão de HRS (uma subunidade do complexo ESCRT-0), ocorreu um acumulo de ?2 em endossomos dilatados contendo HRS-GFP, nos quais também detectou-se CD4 que foi internalizado por Nef. Em conjunto, os resultados indicam que ?2-adaptina é uma importante molécula para o direcionamento de CD4 por Nef para a via ESCRT/MVB, mostrando ser uma proteína relevante no sistema endo-lisossomal. Ademais, os resultados indicaram que as isoformas ?-adaptinas não só possuem funções distintas, mas também parecem compor complexos AP-1 com diferentes funções celulares, já que apenas a variante AP-1 contendo ?2, mas não ?1, participa da regulação negativa de CD4 por Nef. Estes estudos contribuem para o melhor entendimento dos mecanismos moleculares envolvidos na atividade de Nef, que poderão também ajudar na melhor compreensão da patogênese do HIV e da síndrome relacionada. Em adição, este trabalho contribui para o entendimento de processos fundamentais da regulação do tráfego de proteínas transmembrana no sistema endo-lisossomal. / The Human Immunodeficiency Virus (HIV) is the etiologic agent of Acquired Immunodeficiency Syndrome (AIDS). AIDS is a disease which has a global distribution, and it is estimated that there are currently at least 36.9 million people infected with the virus. During the replication cycle, HIV promotes several changes in the physiology of the host cell to promote their survival and enhance replication. The fast progression of HIV-1 in humans and animal models is closely linked to the function of an accessory protein Nef. Among several actions of Nef, one is the most important is the down-regulation of proteins from the immune response, such as the CD4 receptor. It is known that this action causes CD4 degradation in lysosome, but the molecular mechanisms are still incompletely understood. Nef forms a tripartite complex with the cytosolic tail of the CD4 and adapter protein 2 (AP-2) in clathrin-coated vesicles, inducing CD4 internalization and lysosome degradation. Previous research has demonstrated that CD4 target to lysosomes by Nef involves targeting of this receptor to multivesicular bodies (MVBs) pathway by an atypical mechanism because, although not need charging ubiquitination, depends on the proteins from ESCRTs (Endosomal Sorting Complexes Required for Transport) machinery and the action of Alix, an accessory protein ESCRT machinery. It has been reported that Nef interacts with subunits of AP- 1, AP-2, AP-3 complexes and Nef does not appear to interact with AP-4 and AP-5 subunits. However, the role of Nef interaction with AP-1 or AP-3 in CD4 down-regulation is poorly understood. Furthermore, AP-1, AP-2 and AP-3 are potentially heterogeneous due to the existence of multiple subunits isoforms encoded by different genes. However, there are few studies to demonstrate if the different combinations of APs isoforms are form and if they have distinct functional properties. This study aim to identify and characterize cellular factors involved on CD4 down-modulation induced by Nef from HIV-1. More specifically, this study aimed to characterize the involvement of AP-1 complex in the down-regulation of CD4 by Nef HIV-1 through the functional study of the two isoforms of ?-adaptins, AP-1 subunits. By pull-down technique, we showed that Nef is able to interact with ?2. In addition, our data from immunoblots indicated that ?2- adaptin, not ?1-adaptin, is required in Nef-mediated targeting of CD4 to lysosomes and the ?2 participation in this process is conserved by Nef from different viral strains. Furthermore, by flow cytometry assay, ?2 depletion, but not ?1 depletion, compromises the reduction of surface CD4 levels induced by Nef. Immunofluorescence microscopy analysis also revealed that ?2 depletion impairs the redistribution of CD4 by Nef to juxtanuclear region, resulting in CD4 accumulation in primary endosomes. Knockdown of ?1A, another subunit of AP-1, resulted in decreased cellular levels of ?1 and ?2 and, compromising the efficient CD4 degradation by Nef. Moreover, upon artificially stabilizing ESCRT-I in early endosomes, via overexpression of HRS, internalized CD4 accumulates in enlarged HRS-GFP positive endosomes, where co-localize with ?2. Together, the results indicate that ?2-adaptin is a molecule that is essential for CD4 targeting by Nef to ESCRT/MVB pathway, being an important protein in the endo-lysosomal system. Furthermore, the results indicate that ?-adaptins isoforms not only have different functions, but also seem to compose AP-1 complex with distinct cell functions, and only the AP-1 variant comprising ?2, but not ?1, acts in the CD4 down-regulation induced by Nef. These studies contribute to a better understanding on the molecular mechanisms involved in Nef activities, which may also help to improve the understanding of the HIV pathogenesis and the related syndrome. In addition, this work contributes with the understanding of primordial process regulation on intracellular trafficking of transmembrane proteins. AP-1 ESCRT HIV-1 MVB Nef regulação negativa de CD4 y1-adaptina y2-adaptina ?2 depletion and only the AP-1 variant comprising ?2 another subunit of AP-1 AP-1 AP-1 subunits. By pull-down technique AP-2 but not ?1 but not ?1 depletion by flow cytometry assay not ?1-adaptin via overexpression of HRS where co-localize with ?2. Together

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