Refine
Year of publication
- 2019 (4) (remove)
Document Type
- Doctoral Thesis (4)
Has Fulltext
- yes (4)
Is part of the Bibliography
- no (4)
Keywords
- Paramyxoviruses (1)
- Pneumoviruses (1)
Institute
As central component of the peptide loading complex, the ABC transporter TAP is a key player in the adaptive immune response. By recognizing and translocating antigenic peptides derived from proteasomal degradation into the ER lumen it connects the processing of harmful intruders and the marking of an infected cell for elimination. This work focused mainly on the interaction between TAP and one of its viral inhibitors. Of the five known TAP inhibitors, ICP47 is the only one that is not anchored in the ER membrane and has a nonomolar affinity to TAP. These properties and its specific architecture make it an interesting protein engineering tool that can be used in a variety of ways to generate functionally arrested TAP complexes. Different lengths of ICP47 were chosen to map the optimal distance between the binding pocket and the N-terminal elbow helix of either TAP1 or TAP2. I demonstrated that the interaction of fused ICP47 with coreTAP inhibits antigen presentation via MHC I. Interestingly, the loss of MHC I surface expression only depended on the presence of the active domain and not on the length of the fused ICP47 fragments. Summarizing it can be said that TAP complexes containing an intact active domain of ICP47 successfully suppressed MHC I surface expression. Considering the MHC I surface expression in the use of free ICP47 fragments it was revealed that the active domain may not be sufficient. All free constructs, except the one that contains exclusively the active domain (1-35), were able to fully arrest peptide translocation, while the fragment 1-35 partially restored MHC I surface expression. This was the first evidence suggesting that more residues might be present in the ICP47 sequence that contribute to the interaction with TAP.
Further characterization of the ICP47-coreTAP fusion complexes comprised the determination of their thermostability and melting temperatures. The ICP47-coreTAP fusion complexes revealed a preferred orientation for ICP47. The ICP47(1-65) fragment led to a stable complex only if fused to TAP2, highlighting an interesting asymmetry at the TAP1/TAP2 interface, which suggests a shorter distance of the C-terminus of the stabilizing region to the elbow helix of TAP2 than of TAP1. The shorter fragments 1-35 and 1-50, and the ICP47 linker fragments, which inhibited, but did not trigger any thermostabilizing effects on TAP, revealed a second hint for the presence of other residues important for the ICP47/TAP interaction. To define the thermostability in more detail, the melting temperature of complexes with fused or freely bound ICP47 fragments was determined. Short fused fragments of ICP47 (residues 1-35 or 1-50) did not fully stabilize the TAP complex. Only ICP47 fragments longer than residues 1-50 raised the melting temperature to the full extent and led to a completely stabilized complex, suggesting that the critical melting temperature, which determines whether a complex is fully stabilized or not, is about 44-45°C. By comparing different ICP47 proteins from the herpesviral clade, I further noticed that the 21 residues following the active domain are highly conserved. The residues in this region were exchanged by glycines and alanines to study their impact on the thermostabilization of TAP. I demonstrated that several charged residues, an alanine rich, and a proline rich sequence were mainly responsible for the preservation of high melting temperatures. In summary, these findings reveal a dual inhibition mechanism of ICP47. While the active domain of ICP47 is wedged at the TAP1/2 interface and arrests the complex in an open-inward facing conformation, the highly conserved C-terminal region stabilizes the ICP47/TAP interaction and generates a thermostabilized TAP complex.
The second part of this thesis deals with two alternative expression and stabilization strategies for coreTAP, designed to provide a 1:1 ratio of TAP subunits during protein biosynthesis. Different glycine-serine (GS) linkers and a self cleaving 2A site were im- plemented into the TAP sequence and used for comparison with the classical coreTAP. Despite their functionality in antigen translocation, the utilization of GS linkers proved to be unsuitable due to low expression and scarce purification efficiency caused by the unfeasible orthogonal purification. In contrast, the use of a 2A site allowed orthogonal His10- and SBP-tag purification and yielded comparable amounts to the classical coreTAP. However, the ICP47/coreTAP interaction appeared to be hampered by the modified N-terminus of ICP47, due to the cleavage process.
The third and last part of this work deals with the Thermus thermophilus ABC trans- porter TmrAB, which was identified to be part of the same ABC subfamily as TAP. The structure of TmrAB is similar to that of coreTAP and includes a TMD and an NBD for each subunit. In comparison to TAP, TmrAB has a broader substrate range, but it can transport peptides, which are also transported by TAP. Since the natural substrate, and thus the actual function, of TmrAB has not yet been identified, it is counted among the multidrug resistance ABC transporters, from where it also takes its name. In this work, the question was investigated whether TmrAB can be utilized as a TAP substitute. To compare the function of TmrAB and TAP in a natural cell environment, the N-terminal domains of the TAP subunits called TMD0s were fused to the TmrAB subunits and subsequently expressed as different combinations. I found that especially the hybrid complexes containing a TMD0 of TAP2 were functional in terms of MHC I surface expression. Furthermore, TmrAB with TMD0 co-localized prevalently with the ER marker PDI while complexes without TMD0 did not co-localize. Interestingly, the analysis of the interaction with components of the PLC revealed that interaction with tapasin could only occur when a TMD0 was present. In turn, calreticulin, MHC I, and ERp57 were bound, regardless of the presence of a TMD0. It is remarkable that a bacterial protein, sharing only 27-30% sequence identity with human TAP is able to take over a key function of our adaptive immune system. Yet, TmrAB originates from a hyperthermophilic bacterium and may have assembly and folding difficulties that the human cell seeks to overcome by recruiting chaperones like calreticulin and ERp57. Although further experiments will be necessary to analyze the interaction of TmrAB with the PLC components in more detail, TmrAB appears to be homologous to coreTAP, not only in terms of sequence and structure, but also in terms of function.
Das Glykoprotein AICL gehört zur Familie der C-Typ Lektin-ähnlichen Rezeptoren und wird nach Aktivierung humaner NK Zellen und Makrophagen auf deren Oberfläche exprimiert. Die Bindung von AICL an den genetisch gekoppelten, aktivierenden NKRezeptor NKp80, der auf allen reifen humanen NK Zellen exprimiert ist, induziert Effektorfunktionen von NK Zellen, wie Zytotoxizität und Zytokinsekretion. AICL Glykoproteine werden in ruhenden NK Zellen intrazellulär zurückgehalten und gelangen erst nach Zellaktivierung an die Oberfläche (Klimosch et al. 2013). Der Mechanismus dieser Regulation ist bisher unbekannt und sollte im Rahmen dieser Arbeit untersucht werden, um weitere Einblicke in die Funktion des NKp80-AICL Rezeptor-Ligand-Paares im Rahmen einer Immunantwort zu ermöglichen.
In dieser Arbeit konnte gezeigt werden, dass nach der Aktivierung von NK Zellen sowohl präformierte im Golgi-Komplex zurückgehaltene als auch de novo synthetisierte AICL Glykoproteine an die Zelloberfläche gelangen. Bei der intrazellulären Retention von AICL handelt es sich um eine intrinsische Eigenschaft von AICL, die auch im ektopen Kontext von Insektenzellen auftritt. Mechanistisch konnte gezeigt werden, dass die N-Glykosylierungen von AICL differentiell die AICLOberflächenexpression bestimmen. Die AICL Ektodomäne wird an einer nichtkonventionellen (N-X-C) und an drei konventionellen (N-X-S/T) N-Glykosylierungsstellen glykosyliert, wobei die Glykosylierung an ersterer ineffizient ist, sodass stets zwei Glykoisoformen vorhanden sind. Während die Glykosylierung zumindest einer konventionellen Stelle essenziell für die AICL-Oberflächenexpression ist, und diese mit zunehmender Glykosylierung konventioneller Stellen zunimmt, vermindert die nichtkonventionelle Glykosylierungsstelle die AICL-Oberflächenexpression. Für eine effiziente Oberflächenexpression ist auch die Ausbildung einer nicht-konservierten Disulfidbrücke erforderlich, die im membran-distalen Bereich der C-Typ Lektindomäne AICL-Homodimere miteinander verknüpft. Das Fehlen dieser Disulfidbrücke führt auch zu dem Verlust der NKp80-Bindung. Die intrazelluläre Reifung von AICL Glykoproteinen ist, im Gegensatz zu dem verwandten Glykoprotein KACL, in besonderem Maße abhängig von der Interaktion mit den ER-ständigen Proteinen der Proteinqualitätskontrolle. Insbesondere konnte mit Hilfe massenspektrometrischer Analysen eine starke Interaktion von AICL mit dem ER Chaperone Calnexin gezeigt werden. Entsprechend ist die zelluläre Expression von AICL in Abwesenheit von Calnexin stark reduziert. Massenspektrometrisch konnte auch eine spezifische Interaktion von AICL mit dem Protein ITM2A gezeigt werden, wobei allerdings eine funktionelle Relevanz in Folgeversuchen nicht bestätigt werden konnte. Schließlich konnte eine zusätzliche Regulation der AICL-Oberflächenexpression durch proteasomale Degradation nachgewiesen werden, die über zwei Lysine im kurzen zytoplasmatischen Bereich von AICL bestimmt wird.
Frühere Untersuchungen hatten eine Bindung von sowohl AICL- als auch NKp80-Ektodomänen an K562 Zellen, eine Erythroleukämie-zelllinie, ergeben. Da K562 Zellen weder NKp80 noch AICL exprimieren, handelt es sich bei der gebundenen Struktur um einen potenziellen weiteren Liganden des NKp80-AICL Rezeptor-Ligand-Paares. Hier konnte gezeigt werden, dass es sich bei der Bindestruktur um ein Oberflächenprotein der K562 Zellen handelt, das allerdings nicht identifiziert werden konnte.
Insgesamt konnten im Rahmen dieser Arbeit mehrere AICL-spezifische, molekulare Mechanismen identifiziert und charakterisiert werden, die die aktivierungsabhängige Oberflächenexpression von AICL regulieren. Offensichtlich unterliegt diese einer strikten Kontrolle auf mehreren Ebenen, was vermutlich mit der Funktion von AICL als Ligand für einen aktivierenden Immunrezeptor auf zytotoxischen NK Zellen erklärbar ist. Weitere Untersuchungen zur AICL-Expressionsregulation und zur Funktion des NKp80-AICL Rezeptor-Ligand-Paares in vivo sind erforderlich, um ein besseres Verständnis der Immunbiologie von NK Zellen zu erreichen.
Paramyxo- and pneumoviruses include many pathogens with great relevance for human and animal health. To identify common host factors involved in the Paramyxo- and Pneumoviridae life cycle as a basis for new insights in the biology of these viruses and the development of rationally designed therapeutics, genome scale siRNA screens with wild-type measles, mumps, and respiratory syncytial viruses in A549 cells, a human lung adenocarcinoma cell line, were performed. A comparative bioinformatics analysis yielded different members of the coatomer complex I, the translation factors ABCE1 and eIF3A, and several RNA binding proteins as cellular proteins with proviral activity for all three viruses. The strongest common hit, ABCE1, an ATP-binding cassette transporter member, was chosen for further study. We found that ABCE1 supports replication of all three viruses, confirming its importance for both virus families. While viral protein kinetics showed that ABCE1 knockdown resulted in a drastic decrease of MeV protein expression, viral mRNA kinetics are not directly affected by a reduction of ABCE1.
The impact of ABCE1 on viral and global cellular translation was investigated using both 35S metabolic labelling and non radioactive fluorescent protein labelling. ABCE1 knockdown strongly inhibited the production of MeV proteins, while only modestly affecting global cellular protein synthesis and showed that ABCE1 is specifically required for efficient viral, but not general cellular, protein synthesis, indicating that paramyxoand pneumoviral mRNAs may exploit specific translation mechanisms.
In a second approach the efficacy of the small-molecule polymerase inhibitor ERDRP-0519 against MeV was assessed in squirrel monkeys. Animals treated with the drug experienced less severe clinical disease compared to untreated controls, and this effect correlated with the onset of drug treatment.
We observed a reduction of levels of PBMC-associated viremia and virus release in the upper airways, illustrating effective inhibition of virus replication by the drug treatment. ERDRP-0519 drug treatment also alleviated MeV-induced immunosuppression. In addition to providing proof-of-concept for the support of MeV eradication efforts by preventing disease and transmission with a small-molecule polymerase inhibitor, this dissertation provides a novel perspective on cellular proteins that impact the replication of MeV, MuV and HRSV and highlights the role of ABCE1 as host factor that is required for efficient paramyxo- and pneumovirus translation.
ATP-binding cassette (ABC) transporters constitute an omnipresent superfamily of integral membrane proteins, which catalyze the translocation of a multitude of chemically diverse substrates across biological membranes. In humans, ABC transporters typically act as highly promiscuous exporters, responsible for many physiological processes, multi-drug resistance, and severe diseases, such as hypercholesterolemia, lipid trafficking disorders, and immune deficiency. In all ABC transporters, ATP-driven movements within two highly conserved nucleotide-binding domains (NBDs) are coupled to conformational changes of two transmembrane domains (TMDs), which provide a framework for substrate binding and release on the opposite side of the membrane and enable the transporter to cycle between inward-facing and outward-facing orientations. Several structures of ABC transporters determined either by X-ray crystallography or single-particle electron cryo-microscopy (cryo-EM) have been reported, mostly exhibiting a variation of the inward-facing state, which highlights their dynamic behavior. However, for a complete understanding of the conformational dynamics, further structural information on intermediates is needed – especially for heterodimeric ABC transporters, which are predominant in humans and for which only limited structural information is available.
One prime example of such human heterodimeric ABC transport complexes is the transporter associated with antigen processing (TAP). TAP is a key player of the adaptive immune response, because it translocates proteasomal degradation products into the ER lumen for loading of MHC I molecules. Many functional aspects of TAP have been disclosed in recent years. However, structural information is lacking far behind and a major challenge in the field of medical relevant transporters. Recently, the heterodimeric ABC export system TmrAB (Thermus thermophilus multidrug resistance proteins A and B) was identified as an ortholog of TAP, by sharing structural homology with TAP and, intriguingly, being able to restore antigen presentation in human TAP-deficient cells. Thus, TmrAB is a biochemically well-characterized ABC exporter that can be regarded as a functional ortholog of TAP and serves as a model system for (heterodimeric) ABC export systems in general.
Thus, to illuminate the molecular basis of substrate translocation by single-particle cryo-EM, one of the main objectives of this work was the generation of stabilizing chaperones (synthetic antibodies, nanobodies, cyclic peptides) to reduce the conformational heterogeneity of TAP and TmrAB. Selected antibodies were analyzed with respect to stable complex formation, conformational trapping, and the ability to serve as alignment tools for structural studies by single-particle cryo-EM. Both antibody types were shown to form sufficiently stable complexes to serve as a rigid body for EM analyses. However, all selected antibodies bound to the inward-facing state exclusively.
Hence, for EM studies, various ligands were added to elucidate the full spectrum of conformational states during the catalytic cycle. For TAP, first attempts by negative-stain EM revealed a homogenous distribution of particles on the grid. Surprisingly, no transporter-like features were observed although various attempts were applied to increase the overall sample quality.
For TmrAB, in contrast, the complete conformational space in a native-like lipid environment under turnover conditions was mapped. Cryo-EM analysis of TmrAB incubated with ATP-Mg2+ and substrate revealed two distinct inward-facing conformations (IFwide and IFnarrow) as well as two asymmetric conformations with dimerized NBDs, which were markedly different from all previously reported structures. Here, the catalytically active site was slightly wider and contained ADP, while ATP was still bound at the catalytically-inactive site within the NBDs, demonstrating an asymmetric post-hydrolysis state. Intriguingly for the inward-facing conformations, a weak additional density close to residues M139TmrB and W297TmrB was observed in the inward-facing conformation, which displayed a higher degree of cytosolic gate opening (IFwide) indicating the presence of substrate. To verify that this density corresponds to substrate, single alanine mutations of M139TmrB and W297TmrB were introduced, leading to a strong reduction in substrate binding and transport. Since substrate release requires the opening of the extracellular gate, the absence of an outward-facing open conformation indicated that the opening must be highly transient. In order to explore the outward-facing open conformation, a cryo-EM analysis of the catalytically-inactive TmrAE523QB mutant upon incubation with ATP-Mg2+ was performed. Remarkably, within the same dataset, two different outward-facing conformations (occluded and open) were resolved, both in an ATP-bound state, which indicated that binding of ATP is sufficient to drive the large-scale conformational transition from inward-facing to outward-facing open. To explore the effect of nucleotide hydrolysis, TmrAB was trapped by vanadate. Again, two populations were observed, representing the outward-facing open and outward-facing occluded conformation.
Based on several structures of key intermediates, determined under turnover conditions or trapped in the pre-hydrolysis and hydrolysis transition state, for the first time the complete description of the ATP hydrolysis and translocation cycle of a heterodimeric ABC transport complex was elucidated in one single study. By mapping the conformational landscape during active turnover, aided by mutational and chemical modulation of kinetic rates, fundamental and so-far hidden steps of the substrate translocation cycle of asymmetric ABC transporters were resolved and a general template for (heterodimeric) ABC exporter-catalyzed substrate translocation was provided.