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Characterization of mouse NOA1 : subcellular localizaion, G-Quadruplex binding and proteolysis
(2013)
Mitochondria contain their own protein synthesis machinery with mitoribosomes that are similar to prokaryotic ribosomes. The thirteen proteins encoded in the mitochondrial genome are members of the respiratory chain complexes that generate a proton gradient, which is the electromotoric force for ATP synthesis.
NOA1 (Nitric Oxide Associated Protein-1) is a nuclear encoded GTPase that positively influences mitochondrial respiration and ATP production. Although a role in mitoribosome assembly was assigned to NOA1 the underlying molecular mechanism is poorly understood. This work shows that the multi-domain protein NOA1 serves multiple purposes for the function of mitochondria. NOA1 is a dual localized protein that makes a detour through the nucleus before mitochondrial import. The nuclear shuttling is mediated by a nuclear localization signal and the now identified nuclear export signal. SELEX (Systemic Evolution of Ligands by Exponential Enrichment) analysis revealed a G-quadruplex binding motif that characterizes NOA1 as ribonucleoprotein (RNP). G-quadruplex binding was coupled to the GTPase activity and increased the GTP hydrolysis rate. The sequence of localization events and the identification of NOA1 being a RNP lead to the discussion of an alternative import pathway for RNPs into mitochondria. The short-lived NOA1 contains ClpX recognition motifs and is specifically degraded by the mitochondrial matrix protease ClpXP. NOA1 is the first reported substrate of ClpXP in higher eukaryotes and augments the contribution of the ClpXP protease for mitochondrial metabolism. To assess the direct action of NOA1 on the mitoribosome co-sedimentation assays were performed. They showed that the interaction of NOA1 and the mitoribosome is dependent on the GTPase function and the nascent peptide chain. In vitro, NOA1 facilitated the membrane insertion of newly translated and isotope labeled mitochondrial translation products into inverted mitochondrial inner membrane vesicles. In conclusion, NOA1 is a G-quadruplex-RNP that acts as mitochondrial membrane insertion factor for mtDNA-encoded proteins.
This thesis provides a comprehensive model of the molecular function of NOA1 and is the basis for future research. The identification of NOA1 as ClpXP substrate is a major contribution to the field of mitochondrial research.
MHC Klasse I Moleküle liegen im Endoplasmatischen Reticulum (ER) als Dimer bestehend aus einer schweren Kette mit Transmembrandomäne und einem 12 kDa-Protein, dem ß2-Mikroglobulin vor. Nach der Beladung des MHC-Klasse I-Moleküls mit einem antigenen Peptid, welche vorwiegend im Cytosol durch proteasomalen Abbau generiert und durch den Transportkomplex TAP ins ER transloziert werden, findet der Transport des MHC-Peptid-Komplexes zur Zelloberfläche statt. Dort wird das Antigen cytotoxischen T-Zellen präsentiert. An der Assemblierung und Reifung von MHC-Klasse I-Molekülen sind verschiedene Chaperone beteiligt. Eine wichtige Rolle beim Peptidbeladungsprozess von MHC-Klasse I-Molekülen spielt Tapasin. Dabei handelt es sich um ein 48 kDa, MHC-codiertes Typ I Transmembran-Glycoprotein aus der Immunglobulinsuperfamilie. Es verbrückt den TAP-Komplex mit MHC-Klasse I-Molekülen, hält unbeladene MHC-Klasse I-Moleküle im ER zurück und führt eine Qualitätskontrolle des gebundenen Peptids durch. Bei dieser Peptideditierung werden Peptide wieder selektiv aus der MHC-Bindungstasche entfernt, wenn sie mit einer niedrigen Affinität gebunden sind. Dadurch wird sichergestellt, dass keine leeren oder suboptimal beladenen MHC-Peptid-Komplexe an die Zelloberfläche gelangen. In der vorliegenden Arbeit wurde ein System etabliert, mit dem der Einfluss von Tapasin auf die Peptidbeladung von MHC-Klasse I-Molekülen in vitro untersucht werden kann. Dazu wurde ein Verfahren zur heterologen Expression und Reinigung von funktionalem, löslichem Tapasin aus E. coli-Zellen aufgestellt. Weiterhin wurden ß2m und die schwere Kette von HLA-B*2705 heterolog in E. coli-Zellen exprimiert, isoliert und zusammen mit einem Reporterpeptid zum funktionalen HLA-B*2705 renaturiert. Bei Untersuchungen der Wechselwirkung zwischen Tapasin und HLA-B*2705-Molekülen konnte mittels der Oberflächen-Plasmonen-Resonanz-Spektroskopie eine direkte Interaktion zwischen Tapasin und unbeladenem HLA-B*2705 gezeigt werden. Detailliertere Untersuchungen zur Rolle von Tapasin bei der Peptidbeladung wurden mittels einer Gelfiltration gekoppelt mit der Fluoreszenzdetektion des Reporterpeptids durchgeführt. Dabei konnte festgestellt werden, dass unbeladene MHC-Klasse I-Moleküle in Anwesenheit von Tapasin stabilisiert werden und in einer Konformation gehalten werden, die eine Assoziation mit Peptid fördert. Weiterhin wurde gezeigt, dass durch Tapasin die Assoziationsrate für die Peptidbindung erhöht ist. Somit kann in Anwesenheit von Tapasin eine größere Anzahl an Peptiden auf eine stabile und hochaffine Bindung an MHC-Klasse I-Moleküle überprüft werden. In Experimenten mit bereits beladenen MHC-Klasse I-Molekülen konnte gezeigt werden, dass der neugebildetete Komplex auch nach erfolgter Peptidassoziation durch Tapasin stabilisiert wird. Dies ist vermutlich auf eine Erniedrigung der Dissoziationsrate für das Peptid zurückzuführen. Mit dem in dieser Arbeit etablierten Untersuchungssystem ist die Grundlage zu detaillierten Studien der Rolle von Tapasin bei der Peptidbeladung von MHC-Klasse I-Molekülen geschaffen.
Hepatitis B caused by infection with the hepatitis B virus (HBV) still ranks among the most challenging infectious diseases of our time. Despite the availability of an effective prophylactic vaccine, 240 million people worldwide are estimated to be chronically infected with HBV and are at risk of developing life-threatening liver diseases, including cirrhosis and liver cancer. The underlying pathogenic mechanisms of HBV-associated liver diseases are only incompletely understood. It is widely accepted that liver pathology results from long-term immune-mediated liver injury and inflammation as a consequence of inefficient viral elimination. This injury can be naturally compensated by liver regeneration. However, chronic liver damage and permanent inflammation debilitates the regenerative capacity of the liver and fosters fibrosis as well as accumulation of chromosomal aberrations, which both contribute to cirrhosis and liver cancer. Liver regeneration requires the presence of the redox-sensitive transcription factor Nrf2 and intact insulin receptor signaling. A lack of Nrf2 causes increased intracellular levels of reactive oxygen species (ROS) that inactivate insulin receptor signaling and induce insulin resistance. Interestingly, HBV was observed to activate Nrf2 and the expression of Nrf2-regulated genes. This argues against an inhibitory effect of HBV on insulin receptor signaling by increased ROS levels. However, chronic HBV infection is associated with dysregulation of hepatocyte proliferation and retardation of liver regeneration. Hence, the aim of this thesis was to investigate the influence of HBV on the process of liver regeneration with respect to the insulin receptor signaling pathway. After short-term carbon tetrachloride (CCl4)-induced liver damage, HBV transgenic mice present prolonged liver damage and impaired liver regeneration as reflected by reduced hepatocyte proliferation and increased apoptosis. Impaired hepatocyte proliferation in HBV transgenic mice correlates with diminished activation of the insulin receptor. It was further observed in vitro that the activation of Nrf2 by HBV induces increased levels of the insulin receptor mRNA and protein in HBV-expressing cells. Strikingly, stably HBV-expressing cells as well as primary mouse hepatocytes from HBV transgenic mice bind less insulin due to reduced amounts of insulin receptor on the cell surface. This is caused by intracellular retention of the insulin receptor in HBV-expressing cells as a consequence of increased amounts of the cellular trafficking factor α-taxilin. The reduced amounts of insulin receptor on the cell surface impair insulin sensitivity in HBV-expressing cells and inactivate downstream signaling cascades that initiate insulin-dependent gene expression and glucose uptake. As a consequence of impaired hepatocyte proliferation and liver regeneration, HBV transgenic mice exhibit increased development of fibrosis after long-term CCl4-induced liver damage. Taken together, in this thesis, a novel pathomechanism could be uncovered that includes inactivation of insulin receptor signaling by HBV via intracellular retention of the insulin receptor leading to impaired liver regeneration after liver damage and promotion of liver fibrosis. These findings significantly contribute to an enhanced understanding of HBV-associated liver pathogenesis.
The power to dissociate : molecular function of the twin-ATPase ABCE1 in archaeal ribosome recycling
(2010)
Der CD95 Ligand (CD95L, FasL) ist ein Mitglied der Tumor-Nekrose-Faktor(TNF)- Superfamilie und ist in der Lage, Apoptose oder -unter bestimmten Bedingungen- Proliferation in CD95 Rezeptor-positiven Zellen auszulösen. Zusätzlich überträgt der CD95 Ligand aber auch als Rezeptor Signale in die ligandentragende Zelle, ein Phänomen, das auch bei anderen TNF-Familienmitgliedern beobachtet und als "reverse signalling" bezeichnet wird. Diese reverse Signalübertragung bewirkt in T-Zellen ein costimulatorisches Signal, welches zur vollständigen Aktivierung nach Antigen-Erkennung durch den T-Zellrezeptor (TZR) benötigt wird und über bisher unbekannte Adaptorproteine stattfindet, die vermutlich an den intrazellulären Anteil des CD95L binden. Die zytoplasmatische CD95L-Domäne ist auf Primärsequenzebene stark konserviert und besitzt eine prolinreiche Proteininteraktionsdomäne sowie eine Casein Kinase I Phosphorylierungsstelle, welche sich auch im intrazellulären Bereich des membrangebundenen TNFalpha findet und bei diesem Protein für die reverse Signalübertragung essentiell ist. Eine weitere Funktion des CD95L ist der Transport des Liganden zu einem speziellen Typ von Lysosomen in NK- und zytotoxischen T-Zellen. Hierfür ist die prolinreiche Region in der CD95L-intrazellulären Domäne wichtig. In diesen sekretorischen Lysosomen wird der CD95L gespeichert, bis er nach einem TZR-vermittelten Signal an die Zelloberfläche transportiert wird und dort mit dem CD95 Rezeptor der Ziel- Zellen interagieren kann. In der vorliegenden Arbeit wurde zur Aufklärung der oben beschriebenen Funktionen des CD95 Liganden ein Hefe-2-Hybrid Screen mit der intrazellulären CD95L-Domäne als Köder durchgeführt. Mit dieser Methode war es möglich, mehrere potentielle Interaktionspartner zu identifizieren. Eines dieser Proteine, FBP11, wurde schon zuvor als "human fas ligand associated factor" in der Datenbank veröffentlicht. Der HMG-Box-Transkriptionsfaktor Lef- 1, das Formin-bindende Protein FBP11, das thymozytenspezifische Protein TARPP und das Adaptorprotein PSTPIP ("proline serine threonin phosphatase interacting protein")/ CD2BP1 ("CD2 binding protein") interagierten in vitro in einem GST-Pulldown-Experiment mit der intrazellulären Domäne des CD95 Liganden. Mit Hilfe von Co- Immunpräzipitationsstudien und Co-Lokalisierungsexperimenten konnte die Interaktion von überexprimiertem CD95L und PSTPIP auch in vivo bestätigt werden. Des Weiteren wurde in dieser Arbeit gezeigt, dass diese Interaktion über eine nicht näher eingegrenzte Aminosäuresequenz in der prolinreichen Region des CD95L mit der SH3-Domäne des PSTPIP-Proteins realisiert wird. Die Phosphatase PTP-PEST bindet an einen Bereich der PSTPIP-Coiled-coil-Domäne, und es besteht die Möglichkeit, dass CD95L, PSTPIP und PTPPEST in der Zelle als ternärer Komplex vorliegen, in welchem der Phosphorylierungsstatus von PSTPIP und CD95L durch PTP-PEST reguliert wird. Wie die gleichzeitige Expression von PSTPIP die Oberflächenexpression von CD95L beeinflusst, war ein weiterer Untersuchungsgegenstand dieser Arbeit. Es konnte festgestellt werden, dass bei Überexpression von PSTPIP weniger CD95L auf der Oberfläche nachgewiesen wird. Interessanterweise wurde auch weniger Apoptose durch den CD95L ausgelöst, sobald PSTPIP überexprimiert wurde. Neben den Untersuchungen zur Interaktion von CD95L und PSTPIP (sowie PTP-PEST) wurden auch funktionelle Studien zur reversen Signalübertragung des CD95L durchgeführt. Sowohl in CD4- als auch in CD8-einzelpositiven frisch isolierten Maus-T-Zellen wurde ein co-stimulatorisches Signal nach suboptimaler TZR-Stimulation über CD95L beobachtet, was sich in verstärkter Proliferation und erhöhter Expression von Aktivierungsmarkern wie CD25 äußerte. Außerdem führt die Stimulation des CD95 Liganden zu einer transienten p42/p44-MAPK-Phosphorylierung, die durch Co-Expression von PSTPIP jedoch nicht beeinflusst wird. Die MAPK-Signalkaskade führt zur Zellproliferation und könnte daher eine wichtige Rolle in der CD95L-vermittelten Co- Stimulation spielen. Im Rahmen dieser Arbeit konnte auch zum ersten Mal gezeigt werden, dass die Lokalisation des CD95L in Lipid Rafts (Mikrodomänen der Zellmembran) wichtig für dessen apoptoseauslösendes Potential ist, da die Behandlung CD95L-positiver Zellen mit Substanzen, die Cholesterol entfernen und so Rafts zerstören, zur Inhibition der Apoptoseinduktion führt. Die Lokalisation sowohl des CD95 Rezeptors als auch des CD95 Liganden in unterschiedlichen Kompartimenten der Zellmembran könnte beide Moleküle voneinander abschirmen und so autokrine Apoptosemechanismen verhindern. Dadurch wird eine weitere Möglichkeit der Regulation der durch CD95L induzierten Apoptose realisiert.
By adopting a variety of shapes, proteins can perform a wide number of functions in the cell, from being structural elements or enabling communication with the environment to performing complex enzymatic reactions needed to sustain metabolism. The number of proteins in the cell is limited by the number of genes encoding them. However, several mechanisms exist to increase the overall number of protein functions. One of them are post-translational modifications, i.e. covalent attachment of various molecules onto proteins. Ubiquitin was the first protein to be found to modify other proteins, and, faithful to its evocative name, it is involved in nearly all the activities of a cell. Ubiquitylation of proteins was believed for a long time only to be responsible for proteasomal degradation of modified proteins. However, with the discovery of various types of ubiquitylation, such as mono-, multiple- or poly-ubiquitylation, new functions of this post-translational modification emerged. Mono-ubiquitylation has been implicated in endocytosis, chromatin remodelling and DNA repair, while poly-ubiquitylation influences the half-life of proteins or modulates signal transduction pathways. DNA damage repair and tolerance are example of pathways extensively regulated by ubiquitylation. PCNA, a protein involved in nearly all types of DNA transaction, can undergo both mono- and poly-ubiquitylation. These modifications are believed to change the spectrum of proteins that interact with PCNA. Monoubiquitylation of PCNA is induced by stalling of replication forks when replicative polymerases (pols) encounter an obstacle, such as DNA damage or tight DNA-protein complexes. It is believed that monoubiquitylation of PCNA stimulates the exchange between replicative pols to one of polymerases that can synthesize DNA across various lesions, a mechanism of damage tolerance known as translesion synthesis (TLS). Our work has helped to understand why monoubiqutylation of PCNA favours this polymerase switch. We have identified two novel domains with the ability to bind Ub non-covalently. These domains are present in all the members of Y polymerases performing TLS, and were named Ub-binding zinc finger (UBZ) (in polη and polκ) and Ub-binding motif (UBM) (in polι and Rev1). We have shown that these domains enable Y polymerases to preferentially gain access to PCNA upon stalling of replication, when the action of translesion polymerases is required. While the region of direct interaction between Y pols and PCNA had been known (BRCT domain in Rev1 and PIP box motif (PIP) in three others members), we propose that Ub-binding domains (UBDs) in translesion Y pols enhance the PIP- or BRCT-domain-mediated interaction between these polymerases and PCNA by binding to the Ub moiety attached onto PCNA. Following these initial studies, we have also discovered that Y polymerases themselves undergo monoubiquitylation and that their UBDs mediate this modification. This auto-ubiquitylation is believed to lead to an intramolecular interaction between UBD and Ub attached in cis onto the UBD-containing protein. We have mapped monoubiquitylation sites in polη in the C-terminal portion of the protein containing the nuclear localization signal (NLS) and the PIP box. Beside PIP, the NLS motif is also involved in direct interaction of polη with PCNA. Based on these findings, we propose that monoubiquitylation of either NLS or PIP masks them from potential interaction with PCNA. Lastly, using several functional assays, we have demonstrated the importance of all these three motifs in the C-terminus of polη (UBZ, NLS and PIP) for efficient TLS. We have also constructed a mimic of monoubiquitylated polη by genetically fusing polη with Ub. Interestingly, this chimera is deficient in TLS as compared to the wild-type protein. Altogether, these studies demonstrate that the C-terminus of polη constitutes a regulatory module involved in multiple-site interaction with monoubiquitylated PCNA, and that monoubiquitylation of this region inhibits the interaction between polη and PCNA. Our work has also revealed that the UBDs of Y pols as well as of other proteins implicated in DNA damage repair and tolerance, such as the Werner helicase-interacting protein 1 (Wrnip1), are required for their proper sub-nuclear localization. All these proteins localize to discrete focal structures inside the nucleus and mutation of their UBDs results in inability to accumulate in these foci. Interestingly, by exchanging UBDs between different proteins we have learned that each UBD seems to have a distinct functional role, surprisingly not limited to Ubbinding ability. In fact, swapping the UBZ of Wrnip1 with the UBM of polι abolished the localization of Wrnip1 to foci despite preserving the Ub-binding ability of the chimeric protein. In summary, this work provides an overview of how post-translation modification of proteins by Ub can regulate several DNA transactions. Firstly, key regulators (e.g. PCNA) can be differentially modified by Ub. Secondly, specialized UBDs (e.g. UBM, UBZ) embedded only in a subset of proteins act as modules able to recognize these modifications. Thirdly, by means of mediating auto-ubiquitylation, UBDs can modulate the behaviour of host proteins by allowing for either in cis or in trans Ub-UBD interactions.
A great challenge in life sciences remains the site-specific modification of proteins with minimal perturbation for in vitro as well as in vivo studies. Therefore, different chemoselective reactions and semi-synthetic techniques such as native chemical ligation or intein-mediated protein splicing have been established. They enable a site-specific incorporation of chemical reporters into proteins, such as organic fluorophores or unnatural amino acids. In this PhD Thesis, protein trans-splicing was guided by minimal high-affinity interaction pairs to trace proteins in mammalian cells. In addition, the temporal modulation of cellular processes by photo-cleavable viral immune evasins was achieved.
Protein trans-splicing mediated by split inteins is a powerful technique for site-specific and 'traceless' protein modifications. Despite recent developments there is still an urgent need for ultra-small high-affinity intein tags for in vitro and in vivo approaches. So far, only a very few in-cell applications of protein trans-splicing are reported, all limited to C-terminal protein modifications. Here, a strategy for covalent N-terminal intein-mediated protein labeling at sub-nanomolar probe concentrations was developed. Combined with the minimalistic Ni-trisNTA/His-tag interaction pair, the affinity between the intein fragments was increased 50-fold (KD ~ 10 nM). Site-specific and efficient 'traceless' protein modification by high-affinity trans-splicing is demonstrated at nanomolar concentrations in mammalian cells.
High background originating from non-reacted, 'always-on' fluorescent probes still is a crucial issue in life sciences. Covalent labeling approaches with simultaneous activation of fluorescence are advantageous to increase sensitivity and to reduce background signal. Therefore, high-affinity protein trans-splicing was combined with fluorophore/quencher pairs for online detection of covalent N-terminal protein labeling in cellular environments. Substantial fluorescence enhancement at nanomolar probe concentrations was achieved. This ultra-small fluorogenic high-affinity split intein system is an unprecedented example for real-time monitoring of the trans-splicing reaction in cell-like environments as well as for protein labeling with fluorogenic probes at nanomolar concentrations.
To extend the field of chemical immunology and to address spatiotemporal aspects in adaptive immune response, new tools to control antigen processing are required. Therefore, synthetic photo-conditional viral immune evasins were designed to modulate antigen processing on demand. By using light, the time and dose controlled antigen translocation by the transporter associated with antigen processing (TAP) was triggered with response in the second regime. Peptide delivery and loading by the peptide-loading complex (PLC) was rendered inactive, whereas blocking was abolished in a light-controlled fashion to inactivate the synthetic viral immune evasin ICP47 along with simultaneous activation of the antigen presentation pathway. Lightresponsive peptide translocation by the TAP complex was assayed in vitro by utilizing microsomes isolated from professional antigen presenting B-cell lymphomas (Raji). To extend these studies, suppression and photo-controlled rescue of antigen presentation was examined at single-cell resolution in human primary immune cells.
Native chemical ligation interconnects peptide chemistry with recombinantly expressed proteins. This technique was applied to generate the semi-synthetic full-length ICP47. Although this approach was realized, the low product yield was not sufficient for further functional studies. Therefore, full-length ICP47 was consecutively generated by utilizing a full synthetic four-fragment ligation approach. However, this synthetic viral immune evasin was not able to block peptide translocation in a robust way.
Rezeptortyrosinkinasen der Familie der epidermalen Wachstumsfaktorrezeptoren (EGFR) sind in vielen Krebsarten dereguliert und ursächlich an der malignen Transformation beteiligt. Da die Aktivierung vom Rezeptor ausgehender Signaltransduktionskaskaden auf spezifischen Protein-Protein-Interaktionen basiert, kann durch gezielte Interferenz mit diesen Interaktionen das proliferative Signal ausgeschaltet und das Tumorwachstum angehalten werden. Für diese gezielte Interferenz wurde in der vorliegenden Arbeit das Peptid-Aptamer-System eingesetzt, mittels dem Peptide, die in ein Gerüstprotein inseriert sind, aufgrund ihrer Affinität zu einem Zielprotein selektiert werden können. Drei Peptid-Aptamere (KDI1, KDI3, KDI4), die spezifisch mit dem EGF-Rezeptor interagieren, konnten isoliert werden. lntrazelluläre Expression von Peptid-Aptamer KDI1 oder Einbringung des bakteriell exprimierten Peptid-Aptamers KDI1 mittels einer Proteintransduktionsdomäne führte zu reduzierter EGF-abhängiger Proliferation und Transformation. Durch Interferenz des Aptamers mit dem EGF-Rezeptor war die EGF-induzierte Phosphorylierung von Tyrosin 845, 1068 und 1148, sowie die Aktivierung von p46 Shc und STAT3 reduziert. Daher wurde gefolgert, dass das Peptid-Aptamer die EGF-abhängige Rekrutierung der zytoplasmatischen Kinase c-Src an den Rezeptor inhibiert. Durch Fusion einer zusätzlichen Domäne wie der SOCS-Box-Domäne konnte den Peptid-Aptameren eine zusätzliche inhibitorische Funktion gegeben werden. Hierbei handelt es sich um eine Domäne, die spezifisch Kontakt mit E3-Ubiquitin-Ligasen aufbauen kann. Es konnte gezeigt werden, dass durch Transduktion eines solchen Peptid-Aptamers der Rezeptor spezifisch ubiquitinyliert und damit degradiert wird. Das Peptid-Aptamer-System eignet sich somit dazu, Inhibitoren für vorgegebene Zielmoleküle zu isolieren, die sowohl in der Grundlagenforschung als auch in der Tumortherapie Anwendung finden können.
The transporter associated with antigen processing (TAP) plays a pivotal role in the adaptive immune response against virus-infected or malignantly transformed cells. As member of the ABC transporter family, TAP hydrolyzes ATP to energize the transport of antigenic peptides from the cytosol into the lumen of the endoplasmic reticulum. TAP forms a heterodimeric complex composed of TAP1 and TAP2 (ABCB2/3). Both subunits contain a hydrophobic transmembrane domain and a hydrophilic nucleotide-binding domain. The aim of this work was to study the ATP hydrolysis event of the TAP complex and gain further insights into the mechanism of peptide transport process. To analyze ATP hydrolysis of each subunit I developed a method of trapping 8- azido-nucleotides to TAP in the presence of phosphate transition state analogs followed by photocross-linking, immunoprecipitation, and high-resolution SDS-PAGE. Strikingly, trapping of both TAP subunits by beryllium fluoride is peptide-specific. The peptide concentration required for half-maximal trapping is identical for TAP1 and TAP2 and directly correlates with the peptide-binding affinity. Only background levels of trapping were observed for low affinity peptides or in the presence of the herpes simplex viral protein ICP47, which specifically blocks peptide binding to TAP. Importantly, the peptideinduced trapped state is reached after ATP hydrolysis and not in a backward reaction of ADP binding and trapping. In the trapped state, TAP can neither bind nor exchange nucleotides, whereas peptide binding is not affected. In summary, these data support the model that peptide binding induces a conformation that triggers ATP hydrolysis in both subunits of the TAP complex within the catalytic cycle. The role of the ABC signature motif (C-loop) on the functional non-equivalence of the NBDs was investigated. The C-loops of TAP transporter contain a canonical C-loop (LSGGQ) for TAP1 and a degenerated ABC signature motif (LAAGQ) for TAP2. Mutation of the leucine or glycine (LSGGQ) in TAP1 fully abolished peptide transport. TAP complexes with equivalent mutations in TAP2 showed however still residual peptide transport activity. To elucidate the origin of the asymmetry of the NBDs of TAP, we further examined TAP complexes with exchanged C-loops. Strikingly, the chimera with two canonical C-loops showed the highest transport rate whereas the chimera with two degenerated C-loops had the lowest transport rate, demonstrating that the ABC signature motifs control the peptide transport efficiency. All single-site mutants and chimeras showed similar activities in peptide or ATP binding, implying that these mutations affect the ATPase activity of TAP. In addition, these results prove that the serine of the C-loop is not essential for TAP function, but rather coordinates, together with other residues of the C-loop, the ATP hydrolysis in both nucleotide-binding sites. To study the coupling between the ATP binding/hydrolysis and the peptide binding, the putative catalytic bases of the TAP complex were mutated to generate the so-called EQ mutants. The mutations did not influence the peptide-binding ability. Dimerization of the NBDs of EQ mutants upon ATP binding does not alter the peptide binding property. At 27°C, both ATP and ADP could induce the loss of peptide-binding ability (Bmax) only in the variants bearing a mutated TAP2. Further studies are required to deduce at which stage in the catalytic cycle the peptide-binding site is affected. In addition, mutation of the putative catalytic base of both subunits showed a magnesium-dependent peptide transport activity, demonstrating these mutants did not abolish the ATP hydrolysis. Thus, the function of this acidic residue as the catalytic base is not likely to be universe for all ABC transporters.
ABCB9 is a peptide transporter belonging to the ATP-binding cassette (ABC) transporter subfamily B. Due to its high sequence identity to the transporter associated with antigen processing (TAP) the protein was named TAP-like (TAPL). The primary aim of this PhD thesis was the functional characterization of the TAPL transport complex. Despite the lack of TAPL function in the classical MHC class I pathway an involvement of TAPL in antigen presentation was still suggested. Apart from the crucial role of TAP for peptide delivery into the ER, TAP-independent translocation pathways in professional antigen presenting cells (pAPC) have been proposed, but not identified so far. Remarkably, TAPL mRNA and protein expression is strongly induced during differentiation of monocytes to immature and mature dendritic cells. This result was confirmed in the promonocytic cell line THP-1, which was used as a model system for monocyte to macrophage differentiation. By using quantitative immunofluorescence microscopy and subcellular fractionation, TAPL was detected in the lysosomal compartment co-localizing with the lysosome associated membrane protein 2 (LAMP-2) thus excluding the ER-localization formerly reported. Furthermore, by in vitro assays, a TAPL-specific and ATPdependent translocation of peptides into isolated lysosomes was demonstrated. Hence, TAPL is a candidate mediating peptide transport in alternative antigen presentation pathways in pAPCs. The presence of an extra N-terminal transmembrane domain (TMD0) lacking sequence homology to any known protein distinguishes TAPL from most other ABC transporters of its subfamily. By dissecting the TAPL translocation complex into its four putative transmembrane helices containing TMD0 and the core complex, distinct functions to the core complex and TMD0 were assigned. The core-TAPL complex composed of six predicted transmembrane helices and the nucleotide-binding domain (NBD) was expressed transiently in HeLa or stably in Raji cells. Crude membranes containing core-TAPL showed the same peptide transport activity as wt-TAPL demonstrating that the six core helices and the NBD are sufficient for peptide transport. This result also shows that the core transport complex is correctly targeted to and assembled in the membrane. Strikingly, in contrast to the wt transporter, the core complex localizes only partially to lysosomes and is mistargeted to the plasma membrane as observed by immunofluorescence microscopy and confirmed biochemically by cell surface biotinylation. Thus, a crucial role for TMD0 in proper subcellular targeting can be postulated. The vast majority of biological processes are mediated by protein complexes, hence characterization of such protein-protein-interactions is essential for understanding protein function on the cellular level. To identify interaction partners of TAPL, the transporter was isolated by tandem affinity purification. By tandem mass spectrometry the membrane proteins LAMP-1 and LAMP-2 were deciphered as specific proteins interacting with wt-TAPL. Notably, core-TAPL lacks these interactions indicating a role for TMD0 in recruiting other proteins. These results were verified for endogenous TAPL by co-immunoprecipitation. Using cells deficient in LAMP-1 and/or in LAMP-2 an escort function for the LAMP proteins was excluded. Very importantly, the physiological function of the LAMP-1and LAMP-2 interaction with TAPL is an increase in stability, since in their absence half-life of TAPL is drastically reduced.