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Während meiner Promotion habe ich zwei Projekte unter der Aufsicht von Dr. Misha Kudryashev durchgeführt. Im ersten Projekt habe ich die Strukturen des Ryanodinrezeptors 1 (RyR1) in Apo- und Ryanodin-Bindungszuständen in der nativen Membran durch Tomographie und Subtomogramm-Mittelung bei 12,6 bzw. 17,5 Å bestimmt. Im Vergleich zur Struktur von gereinigtem RyR1 unter Verwendung der Einzelpartikel-Kryo-Elektronenmikroskopie (Cryo-EM) können zusätzliche Dichten in der cytoplasmatischen Domäne und der sarkoplasmatischen Retikulum (SR)-Membran bzw. im SR-Lumen beobachtet werden. Die Auflösung der Struktur von RyR1 im Apo-Zustand wurde von den Kollegen in meinem Labor mithilfe der Hybridmethode auf 9,5 Å verbessert. Diese Arbeit hat unser Verständnis für die Mechanismen von RyR1 in nativen Membranen erweitert. Im zweiten Projekt habe ich die Struktur des Proteins SdeC der SidE-Familie durch Einzelpartikel-Kryo-EM bei 4,6 Å bestimmt. Die Kristallstruktur des C-Terminus von SdeA wurde von meinem Forschungspartner Dr. Mohit Misra gelöst. Durch Überlagerung einer gemeinsamen Helix dieser beiden Strukturen konnten wir ein kombiniertes Modell erstellen und ein allgemeines Verständnis der Proteine der SidE-Familie erhalten.
Structure-function relationships in substrate binding protein dependent secondary transporters
(2023)
This work provides new insights into the relevance of SBP dependent secondary transport systems, especially in the thus far under-researched subgroup of TAXI transporters. Importantly, we identified and characterized the TAXI transport system TAXIPm-PQM from Proteus mirabilis. We demonstrated that, in contrast to previously characterized SBP dependent secondary transport systems, TAXIPm-PQM is a proton coupled system and transports the C5-dicarboxylate α- ketoglutarate. Since initially the transport of α-ketoglutarate could only be demonstrated in vivo but not in vitro using established protocols (Mulligan et al. 2009), we investigated in detail the differences between the in vivo and in vitro assay. This resulted in a bioinformatic analysis of TRAP and TAXI signal peptides, which strongly implied that TAXIPm-P requires a transmembrane anchor to allow for transport. We then provided TAXIPm-P surface tethered to the membrane in in vitro transport assays and confirmed the prediction of our bioinformatic analysis that TAXIPm-PQM deploys a membrane-anchored instead of a soluble SBP. Furthermore, the TAXI transport system TAXIMh-PQM from Marinobacter hydrocarbonoclasticus transports fumarate only if both membrane domains Q and M are present. For further characterization, Michaelis-Menten kinetics and affinities were determined for both TAXI transport systems TAXIPm-PQM from Proteus mirabilis and TAXIMh-PQM from Marinobacter hydrocarbonoclasticus. In addition, nanobodies were selected for the membrane domain TAXIPm-QM from Proteus mirabilis to stabilize different conformations which can serve in subsequent structural elucidation studies. Furthermore, the TRAP SBP TRAPHi-SiaP from Haemophilus influenzae was shown to interact not only with its corresponding membrane domain TRAPHi-SiaQM but with at least one additional transporter. It was thereby excluded that TRAPHi- SiaP transfers N-acetylneuraminic acid to the only native E. coli TRAP transporter TRAPEc-YiaMNO and suggested to rather interact with a SBP dependent ABC transport system as this protein family represents the largest SBP dependent protein group in E. coli (Moussatova et al. 2008).
Zika-virus (ZIKV), a flavivirus mainly transmitted by Aedes mosquitoes, is a single-stranded, positive-sense RNA virus. The viral genome is surrounded by a nucleocapsid and a lipid bilayer, in which membrane and envelope proteins are embedded. ZIKV disease is mainly characterized by mild symptoms, such as fever, rash as well as pain in head and joints. However, after epidemics it caused in the Americas in 2015/16, ZIKV infections were also associated with severe neurological complications like the Guillain-Barré syndrome (GBS) and microcephaly in fetuses and newborns. So far there are no specific antiviral treatments or vaccines available against ZIKV. This strengthens the need for a detailed understanding of the viral life cycle and virus-host interactions.
The antiviral host factor tetherin (THN) is an interferon-stimulated protein and therefore part of the cellular innate immune response. It comprises an N-terminal cytoplasmic domain, followed by a transmembrane helix, an extracellular coiled-coil domain and a C-terminal glycosylphosphatidylinositol (GPI) anchor. Containing two sites for membrane insertion linked by a flexible structure, THN is able to integrate into the membrane of budding viruses, thereby attaching them to each other and to the cell membrane and preventing their further release and spread.
In this study, the crosstalk of ZIKV and THN was analyzed. Previous gene expression analyses by microarray and quantitative polymerase chain reaction (qPCR) had revealed a strong upregulation of the BST2 gene encoding for THN in ZIKV-infected cells. However, this enhanced expression did not correlate with an enhanced THN protein level. On the contrary, the amount of THN in THN-overexpressing cells was after infection even heavily reduced. Furthermore, immunofluorescence analyses revealed a loss of THN membrane localization in these cells. By performing a cycloheximide assay, this loss could be traced back to a reduced protein half-life of THN in infected versus uninfected cells. Treatment with inhibitors of different protein degradation pathways as well as colocalization analyses with markers of several subcellular compartments indicated an involvement of the endo-lysosomal route. A knock-down of the ESCRT-0 protein HRS however prevented the sorting of THN for lysosomal degradation and led to a stabilization of THN protein levels. After HRS depletion, the release and spread of viral particles was reduced in THN-overexpressing compared to wildtype cells.
Taken together, the data obtained in this study revealed the potential of THN to restrict ZIKV release and spread. The enhanced degradation of THN in ZIKV-infected cells via the endo-lysosomal pathway could therefore be explained as an effective viral escape strategy. This could be circumvented by knockdown of the ESCRT-0 protein HRS, which highlighted HRS as a potential target for the development of antiviral treatments.
Im Rahmen dieser Arbeit wurden verschiedene metabolische Anpassungsmechanismen des humanpathogenen Bakteriums Acinetobacter baumannii an seinen Wirt untersucht. Im ersten Teil wurde die Rolle von verschiedenen Trimethylammoniumverbindungen (Cholin, Glycinbetain und Carnitin) und den zugehörigen Aufnahmesystemen, sowie ihren Stoffwechselwegen während dieses Prozesses analysiert. Für die Analyse der Transportsysteme wurde eine markerlose Vierfachmutante (Δbcct) von A. baumannii generiert, sodass alle bekannten Transportsysteme für die genannten Verbindungen deletiert vorlagen. Wachstumsversuche mit dieser Mutante zeigten, dass es in A. baumannii keine weiteren Transporter für die Aufnahme von Cholin gibt, jedoch weitere primär aktive oder sekundär aktive Transporter für die Aufnahme von Glycinbetain. Weiterhin konnten innerhalb dieser Arbeit die KM-Werte der Transporter bestimmt werden. Verschiedene Virulenz- und Infektionsanalysen führten zu dem Schluss, dass die Transporter keine Rolle bei der Virulenz von A. baumannii spielen. In Genomanalysen konnten die Gene, die für die Enzyme des Oxidationsweges von Cholin zu Glycinbetain kodieren identifiziert werden (Cholin-Dehydrogenase (betA), GlycinbetainAldehyd-Dehydrogenase (betB) und ein potenzieller Regulator (betI)). Es wurden Deletionsmutanten innerhalb dieses Genclusters generiert, mit dessen Hilfe gezeigt werden konnte, dass Cholin unter Salzstress ausschließlich als Vorläufer für das kompatible Solut Glycinbetain fungiert und nicht als kompatibles Solut von A. baumannii genutzt werden kann. Virulenz- und Infektionsstudien mit den Deletionsmutanten zeigten, dass der Cholin-Oxidationsweg keine Rolle bei der Virulenz von A. baumannii spielt.
Die Cholin-Dehydrogenase BetA wurde zusätzlich in E. coli produziert und anschließend mittels NiNTA-Affinitätschromatographie aufgereinigt. Die biochemische Charakterisierung des Enzyms zeigte, dass BetA membranständig ist und die höchste Aktivität bei einem pH-Wert von 9,0 hat. Salze wie NaCl oder KCl hatten keinen Effekt auf die Aktivität des Enzyms, während Glutamat die Aktivität stimulierte.
Weiterhin konnte FAD als Cofaktor identifiziert werden und der KM-Wert ermittelt werden. Zudem konnte gezeigt werden, dass die Oxidation von Cholin zu Glycinbetain unter isoosmotischen Bedingungen zu einem Anstieg der ATP-Konzentration in A. baumannii-Zellsuspensionen führt und damit, dass Cholin als alternative Energiequelle genutzt wird. Das Phospholipid Phosphatidylcholin konnte als natürliche Cholinquelle identifiziert werden. Eine Rolle der Phospholipasen D bei der Abspaltung der Cholin-Kopfgruppe des Phosphatidylcholins konnte ausgeschlossen werden. Die Gene für die Oxidation von Cholin zu Glycinbetain werden ausschließlich in Anwesenheit von Cholin exprimiert, jedoch unabhängig von der extrazellulären Salzkonzentration. Diese Studien zeigten, dass der Cholin-Oxidationsweg eine Rolle in der metabolischen Adaptation von A. baumannii an den Wirt spielt. Phosphatidylcholin kann hier als natürliche Cholinquelle im Wirt genutzt werden, da die Wirtsmembranen aus bis zu 70 % Phosphatidylcholin bestehen. Transportstudien mit Carnitin führten zu dem Schluss, dass der Transporter Aci01347 aus A. baumannii neben Cholin ebenfalls Carnitin transportiert. Wachstumsversuche mit einer aci01347-Mutante bestätigen, dass Aci01347 essenziell für die Aufnahme und anschließende Verwertung von Carnitin als Kohlenstoffquelle ist. Es konnte weiterhin gezeigt werden, dass das Transportergen mit essenziellen Genen für den Carnitin-Abbau in einem Operon liegt. Für die Analyse des Abbauweges von Carnitin wurden markerlose Deletionsmutanten innerhalb des Operons generiert. In Wachstumsstudien mit diesen Mutanten konnte der Abbauweg aufgeklärt werden und der Regulator des Operons identifiziert werden. Carnitin wird hier über Trimethylamin und Malat-Semialdehyd zu D-Malat umgewandelt und anschließend über Pyruvat in den TCA-Zyklus eingespeist. Der Regulator wurde zusätzlich in E. coli produziert und mittels Ni-NTA-Affinitätschromatographie aufgereinigt. Mithilfe von EMSA-Studien konnte die Bindestelle des Regulators auf eine 634 Bp lange DNA-Sequenz stromaufwärts des CarnitinOperons eingegrenzt werden. Durch Transkriptomanalysen konnte gezeigt werden, dass bei Wachstum mit Acetylcarnitin, Carnitin und D-Malat die Expression des Carnitin-Operons induziert wurde. Darüber hinaus wurden die Gene konservierter Aromatenabbauwege wie z. B. des Homogentisatweges, des Phenylacetatweges und des Protocatechuat-Abbaus, verstärkt exprimiert. In G. mellonellaVirulenzstudien konnte eine Rolle des Abbaus von Carnitin bei der Virulenz von A. baumannii nachgewiesen werden. Zusätzlich konnte dieser Effekt dem entstehenden Trimethylamin zugesprochen werden...
Mechanistic and structural insights into the quality control of the MHC I antigen processing pathway
(2022)
The human body is permanently exposed to its environment and thus to viruses and other pathogens, which require a flexible response and defense. Alongside to the innate immune system, the adaptive immune system provides highly specialized protection against these threats. The major histocompatibility complex class I (MHC I) antigen presentation system is a cornerstone of the adaptive immune system and a major constituent of cellular immunity. Pathogens such as viruses that invade a cell will leave traces in the form of proteins and peptides which are degraded and loaded onto MHC I molecules. MHC I peptide loading is performed by peptide loading complex (PLC) in the membrane of the endoplasmic reticulum as part of a multifaceted and comprehensive quality control machinery. Monitored by multiple layers of quality assurance, the MHC I molecules consequently display the immune status of the cell on its surface. In this context, the captured fragment of the virus serves as a call for help issued by the cell, alerting the adaptive immune system to the infection to mount an appropriate immune response.
The three-dimensional structure as well as the mechanistic details of parts of this complex machinery were characterized in the context of this dissertation. Among other tools, light-modulable nanotools were developed in this thesis, which permit external regulation of cellular processes in temporal and spatial resolution. Furthermore, methods and model systems for the biochemical characterization of cellular signaling cascades, proteins, as well as entire cell organelles were developed, which are likely to influence the field of cellular immunity and protein biochemistry in the future.
This cumulative work comprises a total of six publications whose scientific key advances will be briefly outlined in this abstract. In the introduction, the scientific background as well as the current state of research and methodological background knowledge are conveyed. The results section condenses the main aspects of the publications and links them to each other. Further details can be retrieved from the attached original publications.
In “Semisynthetic viral inhibitor for light control of the MHC I peptide loading complex, Winter, Domnick et al., Angew Chem Int Ed 2022” a photocleavable viral inhibitor of the peptide loading complex was produced by semi-synthesis. This nanotool was shown to be suitable for both purifying the PLC from human Raji cells as well as reactivating it in a light-controlled manner. Thus, this tool establishes the isolation of a fully intact and functional peptide loading complex for biochemical characterization. In addition, a novel flow cytometric analysis pipeline for microsomes was developed, allowing cellular vesicles to be characterized with single organelle resolution, similar to cells.
In “Molecular basis of MHC I quality control in the peptide loading complex, Domnick, Winter et al., Nat Commun 2022” the peptide loading complex was reconstituted into large nanodiscs, and a cryo-EM structural model of the editing module at 3.7 Å resolution was generated. By combining the structural model with in vitro glycan editing assays, an allosteric coupling between peptide-MHC I assembly and glycan processing was revealed, extending the known model of MHC I loading and dissociation from the PLC. These mechanisms provide a prototypical example for endoplasmic reticulum quality control.
In a related context, in “Structure of an MHC I–tapasin–ERp57 editing complex defines chaperone promiscuity, Müller, Winter et al., Nat Commun 2022” a recombinantly assembled editing module comprised of MHC I-tapasin-ERp57 was crystallized for X-ray structural biology. The resulting crystal structure at a resolution of 2.7 Å permitted the precise identification of characteristic features of the editing module and particularly of the peptide proofreading mechanism of tapasin. This study provided pivotal insights into the tapasin-mediated peptide editing of different MHC I allomorphs as well as similarities to TAPBPR-based MHC I peptide proofreading.
In “TAPBPR is necessary and sufficient for UGGT1-mediated quality control of MHC I, Sagert, Winter et al. (in preparation)” novel insights concerning the peptide proofreader TAPBPR and its close interplay with the folding sensor and glucosyltransferase UGGT1 were obtained. It was shown that TAPBPR is an integral part of the second level of endoplasmic quality control and is indispensable for effective MHC I coordination by UGGT1.
In “Light-guided intrabodies for on-demand in situ target recognition in human cells, Joest, Winter et al., Chem Sci 2021” intracellular nanobodies were equipped with a photocaged target recognition domain by genetic code expansion via amber suppression. These intrabodies, acting as high-affinity binding partners endowed with a fluorophore, could be used in a light-triggered approach to instantaneously visualize their target molecule...
Locomotion, the way animals independently move through space by active muscle contractions, is one of the most apparent animal behaviors. However, in many situations it is more beneficial for animals to actively prevent locomotion, for instance to briefly stop before reorienting with the aim of avoiding predators, or to save energy and recuperate from stress during sleep. The molecular and cellular mechanisms underlying such locomotion inhibition still remain elusive. So, the aim of this study was to utilize the practical genetic model organism Caenorhabditis elegans to efficiently tackle relevant questions on how animals are capable of suppressing locomotion.
Nerve cells, mostly called neurons, are known to control locomotion patterns by activating some and inhibiting other muscle groups in a spatiotemporal manner via local secretion of molecules known as neurotransmitters. This study particularly focuses on whether neuropeptides modulate such neurotransmission to prevent locomotion. Neuropeptides are small protein-like molecules that are secreted by specific neurons and that act in the brain by activating G protein-coupled receptors (GPCRs) expressed in other target neurons. They can act as hormones, neuromodulators or neurotransmitters. DNA sequences coding for neuropeptides and their cognate receptors are similar across diverse species and thus indicate evolutionary conservation of their molecular signaling pathways. This could potentially also imply that regulatory functions of specific neuropeptides are also similar across species and are thus meaningful to unravel more general mechanisms for instance underlying locomotion inhibition.
Specifically, we find that the modulatory interneuron RIS constitutes a dedicated stop neuron of which the activity is sufficient to initiate rapid locomotion arrest in C. elegans while maintaining its body posture. Similar to its known function in larval sleep, RIS requires RFamide neuropeptides encoded by the flp 11 gene for this activity, in addition to GABA. Furthermore, we find that spontaneous calcium activity transients in RIS are compartmentalized and correlated with locomotion stop. These findings illustrate that a single neuron can regulate both stopping and sleeping phenotypes.
Secondly, we show that C. elegans RPamide neuropeptides encoded by nlp-22 and nlp-2 regulate sleep and wakefulness, respectively. We unexpectedly find that these peptides activate gonadotropin-releasing hormone (GnRH)-like receptors dose dependently and we highlight their sequence resemblance to other bilaterian GnRH-like neuropeptides. In addition, we show that these receptors are expressed in distinct subsets of neurons that are associated with motor behavior. Finally, we show that nlp 22 encoded peptides signal through GNNR 6 receptors to regulate larval sleep and that nlp 2 encoded peptides require both GNRR 3 and GNRR 6 receptors to promote wakefulness.
In sum, we find that locomotion inhibition in C. elegans is regulated by multiple, but evolutionary conserved RFamide and GnRH-like RPamide neuropeptidergic signaling pathways.
This thesis investigates the structure of the translocase of the outer membrane (TOM) complex in mitochondria, focusing on the TOM holo complex through single-particle electron cryo-microscopy (cryoEM) complemented by mass spectrometry and computational structure prediction. Mitochondria, crucial for energy production in eukaryotic cells, import most of their proteins from the cytoplasm. These proteins enter through the TOM complex, which in its core form consists of a membrane-embedded homodimer of Tom40 pores, two Tom22 cytoplasmic receptors, and six small TOM stabilizing subunits (Tom7, Tom6, and Tom5). The holo complex includes two additional subunits, Tom70 and Tom20, whose stoichiometry and positioning are less understood due to their easy dissociation during isolation of the complex. CryoEM analysis revealed the high-resolution structure of the Neurospora crassa TOM core complex at 3.3 Å, containing all core subunits, and the presence of a central phospholipid causing the Tom40 dimer to tilt to 20°. Furthermore, a 4 Å resolution map indicated the binding of a precursor protein as it transitions through the translocation barrel. Finally, at 6-7 Å resolution, the structure of the TOM holo complex highlighted Tom20's flexibility as it interacts with the core complex, emphasizing its role in protein translocation. This work provides significant insights into the architecture and functioning of the TOM complex, contributing to the understanding of mitochondrial protein import mechanisms.