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Das Hauptziel dieser Dissertation lag in der Verbesserung einzelner Schritte im Prozess der automatischen Proteinstrukturbestimmung mittels Kernmagnetischer Resonanz (NMR). Dieser Prozess besteht aus einer Reihe von sequenziellen Schritten, welche zum Teil bereits erfolgreich automatisiert wurden. CYANA ist ein Programmpaket, welches routinemäßig zur automatischen Zuordnung der chemischen Verschiebungen, der Nuclear Overhauser Enhancement (NOE) Signalen und der Strukturrechnung von Proteinen verwendet wird. Einer der Schritte, der noch nicht erfolgreich automatisiert wurde, stellt die Signalidentifizierung von NMR Spektren dar. Dieser Schritt ist besonders wichtig, da Listen von NMR-Signalen Grundlage aller Folgeschritte sind. Fehler in den Signallisten pflanzen sich in allen Folgeschritten der Datenauswertung fort und können am Ende in falschen Strukturen resultieren. Daher war ein Ziel dieser Arbeit, einen robusten und verlässlichen Algorithmus zur Signalidentifizierung von NMR Spektren in CYANA zu implementieren. Dieser Algorithmus sollte mit dem in FLYA implementierten Ansatz zur automatischen Resonanzzuordnung, der automatischen NOE-Zuordnung und der Strukturrechnung mit CYANA kombiniert werden. Der in CYANA implementierte CYPICK Algorithmus ahmt den von Hand durchgeführten Ansatz nach. Bei der manuellen Methode schaut sich der Wissenschaftler zweidimensionale Konturliniendarstellungen der NMR Spektren an und entscheidet anhand verschiedener Geomtrie- und Ähnlichkeitskriterien, ob es sich um ein Signal des Proteins oder um einen Artefakt handelt. Proteinsignale sind ähnlich zu konzentrischen Ellipsen und erfüllen bestimmte geometrische Kriterien, wie zum Beispiel ungefähr kreisförmiges Aussehen nach entsprechender Skalierung der spektralen Achsen und gänzlich konvexe Formen, die Artefakte nicht aufzeigen. CYPICK bewertet die Konturlinien lokaler Extrema nach diesen Bedingungen und entscheidet anhand dieser, ob es sich um ein echtes Signal handelt oder nicht. Das zweite Ziel dieser Arbeit war es ein Maß zur Quantifizierung der Information von strukturellen NMR Distanzeinschränkungen zu entwickeln. Der sogenannte Informationsgehalt (I) ist vergleichbar mit der Auflösung in der Röntgenkristallographie. Ein weiteres Projekt dieser Dissertation beschäftigte sich mit der strukturbasierten Medikamentenentwicklung (SBDD). SBDD wird meist von der Röntgenkristallographie durchgeführt. NMR hat jedoch einige Vorteile gegenüber der Röntgenkristallographie, welche interessant für SBDD sind. Daher wurden Strategien entwickelt, die NMR für SBDD zugänglicher machen sollen.
Necroptosis is an immunogenic form of programmed cell death characterized by plasma membrane accumulation of activated mixed lineage kinase domain-like (MLKL) that eventually leads to membrane disruption and release of danger-associated molecular patterns (DAMPs). Necroptotic cell death is tightly controlled by checkpoints, including compartmentalization as well as post-translational modifications (PTMs), like phosphorylation and ubiquitination of receptor-interacting protein kinase (RIPK) 1, RIPK3 and MLKL. Removal of plasma membrane-located activated MLKL via endocytosis or exocytosis can counteract necroptosis, but up till now, the exact mechanisms by which necroptosis is regulated downstream of MLKL activation and oligomerization are not fully understood.
Ubiquitination is a key post-translational modification that regulates various cellular processes including cell survival and cell death signaling via ubiquitination of RIPK1, RIPK3 and MLKL. M1-linked (linear) poly-ubiquitination is mediated exclusively by the linear ubiquitin chain assembly complex (LUBAC) which critically regulates cell fate and immune signaling via death receptors such as TNF receptor 1 (TNFR1).
In this study, we demonstrate that M1 poly-Ubiquitin (poly-Ub) increases during necroptosis which can be blocked by inhibition of LUBAC activity with the small-molecule HOIL-1-interacting protein (HOIP) inhibitor HOIPIN-8 or by loss of LUBAC catalytic subunit HOIP. Intriguingly, HOIPIN-8, as well as the HOIP inhibitor gliotoxin, and HOIP knockdown effectively prevent TNFα/smac mimetic/zVAD.fmk-induced necroptotic cell death in cells of human origin, without affecting necroptotic RIPK1 and RIPK3 phosphorylation, necrosome formation and oligomerization of phosphorylated MLKL. We demonstrate that HOIPIN-8 treatment inhibits MLKL translocation to intracellular membranes and accumulation in plasma membrane hotspots as well as MLKL exocytosis. We further confirm that HOIPIN-8 treatment suppresses necroptotic cell death in primary human pancreatic organoids (hPOs). Using time-lapse imaging and live/dead staining, we demonstrate loss of organoid structure and hPO cell death induced by smac mimetics and caspase inhibitors, thus providing a novel platform to investigate necroptosis in near physiological settings. Inhibition of LUBAC activity with HOIPIN-8 prevents hPO collapse and extends cell viability. Of note, loss of the M1 Ub-targeting deubiquitinating enzymes (DUBs) OTU DUB with linear linkage specificity (OTULIN) and cylindromatosis (CYLD) in human cell lines does not affect necroptosis induction and HOIPIN-8-mediated rescue of necroptosis. Intriguingly, inhibition of LUBAC activity with HOIPIN-8 does not block necroptotic cell death in murine cell lines.
Using massive analyses of cDNA ends (MACE)-seq-based global transcriptome analysis we confirm that necroptosis induces a pro-inflammatory cytokine profile which is dependent on LUBAC function and necroptotic signaling. Loss of LUBAC activity prevents the MLKL-dependent production and release of pro-inflammatory cytokines and chemokines.
Finally, we identify Flotillin-1 and -2 (FLOT1/2) as putative targets of necroptosis-induced M1 poly-Ub. Ubiquitin-binding in ABIN and NEMO (UBAN)-based pulldowns of M1 poly-ubiquitinated proteins revealed enrichment of FLOTs after necroptosis induction which is dependent on LUBAC activity and can be blocked with necroptosis inhibitors Nec-1s, GSK’872 and NSA, targeting RIPK1, RIPK3 and MLKL, respectively. Of note, loss of FLOT1/2 potentiates necroptosis suppression induced by LUBAC inhibition with HOIPIN-8.
Together, these findings identify LUBAC-mediated M1 poly-Ub as an important mediator of necroptosis and identify FLOTs as novel putative targets of LUBAC-mediated M1 poly-Ub during necroptosis. In addition, by modeling necroptosis in primary human organoids, we further expand the spectrum of experimental models to study necroptosis in human cellular settings.
The transcription factor p63 is part of the p53 protein family, which consists of three members, p53, p63 and p73. P63 shares structural similarity with all family members, but is associated to different biological functions than p53 or p73. While p53 is mainly linked to tumor suppression and p73 is connected with neuronal development, p63 has been connected to critical biological roles within ectodermal development and skin stem cell biology as well as supervision of the genetic stability of oocytes. Due to its gene structure p63 is expressed as at least six different isoforms, three of them containing a N-terminal transactivation domain. The isoforms that are of biological relevance both have a C-terminal inhibitory domain that negatively regulates the transcriptional activity. This inhibitory domain is supposed to contain two individual components of which one is internally binding and masking the transactivation domain while the other one can be sumoylated. To further investigate this domain a mutational analysis with the help of transactivation assays in SAOS2 cells was carried out to identify the critical amino acids within the inhibitory domain and the impact on transcriptional activity of TAp63alpha, the p63-isoform which is essential for the integrity of the female germline. The results of these experiments show that a stretch of approximately 13 amino acids seems to be important for the regulation of transcriptional activity in TAp63alpha, due to the increased transcriptional activity occurring in this region after mutation. Additional experiments showed that this mechanism is distinct from sumoylation, which seems to have only implications for the intracellular level of TAp63alpha. As a conclusion, the C-terminus of the Tap63alpha is essential for two different mechanisms, which control the transcriptional activity of the protein. Both regulatory elements are independent from each other and can now be restricted to certain amino acids. Activation of the wild type protein might take place in the identified region via post-translational modification. Furthermore an inhibition assay was carried out to test if the same region might have implications on the second biological relevant isoform deltaNp63alpha. The results show that the same amino acids which show an impact on transcriptional activity in Tap63alpha lead to a significant change in functional behaviour of deltaNp63alpha. There is a possibility that both proteins are regulated with opposite effects via the same mechanisms, based at the C-terminus of the p63alpha-isoforms. In both cases a modification of these residues could lead to a more opened conformation of the protein with consequences on promoter binding, which can be even important for deltaNp63alpha with respect to promoter squelching. Both alpha-isoforms seem to be regulated via the C-terminus and to elucidate if that is also the case for TAp63gamma a deletion analysis was carried out. The results show that there are also amino acids within the C-terminus of TAp63gamma, which have implications on the transcriptional activity of the protein. Therefore the C-terminus seems to play a major role for regulation of diverse p63 isoforms.
Der 2‘-Desoxyguanosin-Riboschalter gehört zur unter Bakterien weit verbreiteten Klasse der Purin-Riboschalter. Allerdings wurden 2‘-Desoxyguanosin-bindende Riboschalter bisher ausschließlich in M. florum gefunden, damit stellt diese RNA eine Ausnahme unter den ansonsten verbreiteten Purin-Riboschaltern dar. In der vorliegenden Arbeit wurde ein NMR-Strukturmodell des IA-Aptamer-2‘-Desoxyguanosinkomplexes erstellt und anhand der mittels NMRSpektroskopie zugänglichen strukturellen Informationen sowohl Struktur und Dynamik des freien RNA-Aptamers als auch des 2‘-Desoxyguanosinkomplexes charakterisiert. Dabei wurde insbesondere der Einfluss von Mg2+ auf Struktur und Dynamik der jeweiligen Zustände sowie auf den durch 2‘-Desoxyguanosin induzierten Faltungsprozess untersucht.
Mg2+-Ionen modulieren die Faltungstrajektorien von sensorischen RNA-Domänen. Die Übertragbarkeit von Mg2+-abhängigen Charakteristika der RNA-Faltung innerhalb verschiedener Messmethoden ist durch die schlechte Vergleichbarkeit der relativen Konzentrationsverhältnisse eingeschränkt. Die NMR-spektroskopisch beobachtbaren Mg2+-Einflüsse sollten also unter besonderer Berücksichtigung der für NMR benötigten vergleichsweise sehr hohen RNAKonzentrationen mit Ergebnissen aus kalorimetrischen oder fluoreszenzspektroskopischen Messungen interpretiert werden. Die in der NMR-Spektroskopie üblichen hohen Probenkonzentrationen befinden sich in dem Regime, in dem auch der physikalische Effekt des verdrängten Volumens eine Rolle zu spielen beginnt. Demnach ist es für die RNA-Moleküle im NMR-Probenröhrchen bei Konzentrationen von 5-10 mg/ml auch ohne Zugabe von Mg2+ entropisch günstiger, kompakte Konformationen einzunehmen. Die Relevanz des Effekts des verdrängten Volumens für die RNA-Faltung unter NMR-Bedingungen und unter zellulären Bedingungen ist Gegenstand der aktuellen Forschung und wird in dieser Arbeit am Beispiel des IA-Aptamers diskutiert.
Der oft einzigartige Bindungsmodus ubiquitärer Metaboliten durch bakterielle Riboschalter (Montange and Batey, 2006) ermöglicht prinzipiell den Einsatz von RNA-Aptameren in vivo, ohne mit zellulären Proteinsystemen zu interferieren (Mulhbacher et al., 2010). Therapeutische Ziele sind beispielsweise die Anwendung von Riboschaltern gegen bakterielle Pathogene beziehungsweise gegen pathogene Bakterien selbst. Eine weitere Rolle wird RiboschalterElementen zukünftig als Bausteine in der synthetischen Biologie zukommen (Dixon et al., 2010; Knight, 2003; Topp and Gallivan, 2008). Hierfür ist es von grundlegender Bedeutung, Charakterisierung von Struktur als Basis für das Verständnis von Funktion unter zellulären Bedingungen zu etablieren. Im Rahmen einer Zusammenarbeit mit Robert Hänsel aus dem Arbeitskreis von Prof. Dr. Volker Doetsch wurde am Beispiel des IA-Aptamers und einer nichtnatürlichen Sequenzvariante gezeigt, dass eine strukturelle Charakterisierung von Riboschaltern mittels in cell NMR-Spektroskopie möglich ist. In Zusammenarbeit mit Karl von Laer aus der Arbeitsgruppe von Prof. Dr. Beatrix Suess wurden beide RNA-Aptamer hinsichtlich ihrer Funktion in einem biologischen Assay getestet. Die Ergebnisse dieser Experimente zeigten eine deutliche Korrelation von Struktur und Funktion in vivo, während Diskrepanzen zwischen Struktur in vitro und Funktion in vivo demonstriert werden.
Weiterhin wurde im Rahmen dieser Arbeit gezeigt, dass eine gewisse strukturelle Flexibilität der Bindungstaschen regulatorischer RNA-Motive für Selektion und Adaption während Evolution nötig ist. Beispielsweise wurde für den Guanin-Riboschalter gezeigt, dass der nicht-native Ligand 2‘-Desoxyguanosin zur Komplexbildung des Aptamers führt. Demnach könnte die Bindung von 2‘-Desoxyguanosin im Guanin-Riboschalter bereits evolutionär angelegt sein und die Entstehung des IA-Aptamers nach Genomreduktion der Mesoplasmen begünstigt haben. Das IA-Aptamer dagegen bindet Guanin nicht, stattdessen besitzt M. florum auf Guanin spezialisierte Sequenzvarianten dieses Riboschalters (Kim et al., 2007). Strukturell hochauflösende Einblicke in unterschiedliche Zustände der Bindungstasche im G-Aptamer-Thioguaninkomplex, die durch die Lösung der Kristallstruktur des GLoop-Aptamers ermöglicht wurden, unterstützen die Hypothese einer anpassungsfähigen Bindungstasche im G-Aptamer. Für B. subtilis wäre es interessant, die physiologische Bedeutung der Komplexbildung des G-Aptamers mit 2‘-Desoxyguanosin zu untersuchen.
So far clinical human immunodeficiency virus (HIV) therapy is limited to non-curative treatments. However, as recently shown, alternative approaches such as HIV gene therapy have the potential to functionally cure the disease (e.g. the hematopoietic stem cell (HSC)-transplantation with a CCR5Δ32 homozygous transplant) (1). In contrast to the highly personalized medical treatment applied in the ‘Berlin case’, more broadly applicable approaches are currently under intensive investigation.
One example is the adeno-associated-virus (AAV)-mediated delivery of in vivo secreted antiviral entry inhibitors (iSAVE), the concept of which is based on the direct in vivo administration of a broadly applicable highly potent antiviral gene (here: a C46-derived entry inhibitory peptide interfering with HIV-1 membrane fusion). The AAV-based gene delivery is believed to overcome several limitations of gene therapeutic treatments based on ex vivo lentiviral trials in the past. It is (i) targeting differentiated HIV target cells (i.e. liver and differentiated lymphatic cells) reducing the risk of genotoxicity compared to stem cell-based trials, (ii) overcoming the limitation of a low number of genetically modifiable cells as in lentivirally based ex vivo transduction strategies (i.e. limited modifiable cell number due to culture conditions and lower vector titers) and (iii) using the safe AAV vector system, which has not been associated with major genotoxicity in men. (iv) Most importantly, the concept of secretable entry inhibitors does not require transduction of large amounts of cells due to the protective bystander effect. Thus, iSAVE might be a treatment principle for HIV infection that might be able to cure patients irrespective of their viral isolates or adherence.
Accordingly, the iSAVE concept could aim at two different sites in the patient for the production of antiviral transgenes, either the systemic production via suitable producer cells (e.g. hepatocytes) or the local production in the lymphatic system.
In a first approach, we are able to efficiently target hepatocytes using the natural AAV serotype 8 to express high plasma levels of secretable antiviral entry inhibitors in order to systemically suppress viral replication. In this setting we could show that iSAVE peptides are highly expressed in hepatocytes. However, plasma levels of iSAVE were insufficient when using a secretable peptide as sole antiviral transgene.
As a second treatment strategy, the iSAVE project aimed to deliver antiviral genes directly to the site of viral replication, the lymphatic system. Here, (i) a panel of naturally occurring AAV serotypes as well as (ii) AAV retargeting approaches were employed to design a highly efficient and selective AAV vector variant for gene delivery into the lymphatic system after intravenous vector administration.
In detail, (i) screening of the natural occurring serotypes revealed that the AAV serotype 1 (AAV-1) was best in targeting splenic tissue in two humanized mouse models, however at a very low level. After systemic AAV-1 vector administration neither transduction of human lymphocytes did occur nor was iSAVE expressed in the lymphatic system in a humanized mouse model.
(ii) In a second approach, we modified the well-characterized AAV-2 serotype in a tropism-defining region of its capsid gene by insertion of human peripheral blood lymphocytes (hPBL)-tropic peptide ligands. These in turn were selected by M13 in vivo phage display and by in vivo AAV peptide display. Selected variants were cloned and tested for hPBL transduction in vitro. Although the selected variants did not show increased expression efficacies compared to AAV-2 WT, it still might be possible that the selected variant are more specific for hPBLs as these conditions have not been tested.
As these selection processes required a humanized mouse model that comprises a functional lymphatic system, we established the previously described Trimera mouse model in our lab (2). We found that this mouse model could be further improved to allow engraftment of a lower number of gene-modified (gm) human T cells as in the classical Trimera model. These modified Trimera mice (mT3 mice) were conditioned by inclusion of cyclophosphamide (CTX) to the irradiation-conditioning scheme of the classical Trimera model.
Comparison of mT3 mice with established NSG and DKO mice in an adoptive gm T cell transplantation setting revealed that NSG mice were the most robust model providing high reproducibility in human T cell engraftment. MT3 mice allowed a substantial, yet more variable engraftment of gm T cells. Besides comparing engraftment kinetics, the graft quality (i.e. clonality and cytokine milieu) was analyzed. Again, NSG mice showed the most balanced homeostatic repopulation three weeks after transplantation, while mT3 mice were prone to Th1-type, oligloclonal repopulation, indicating an early onset of xenograft-versus-host disease. Finally, the lymphatic infiltration was analyzed. As expected, mT3 mice provided the most intact lymphatic structures, although the normal lymphatic morphology was not restored.
In conclusion, it was demonstrated in this work that AAV-mediated iSAVE gene therapy faces specific limitations depending on the respective targeting approach
In the systemic approach, iSAVE peptides have to be further optimized in terms of transgene design itself, as high-level accumulation in murine plasma was not feasible for the short iSAVE precursor. In the local, lymphatic targeting approach, AAV-mediated expression faces its limits in targeting specificity but foremost expression efficacy. Thus, the AAV vector itself needs further optimization for sufficient local iSAVE expression levels. Independently from the AAV-related approaches, a novel humanized mouse model was established in this work. Despite drawbacks regarding repopulation variability and set-up complexity, the novel mT3 mouse model comprised improved secondary lymphatic structures for adoptive T cell transfer, which might be an interesting platform for studies in lymphoma or leukemia therapy.
In this thesis the integral membrane protein diacylglycerol kinase (DAGK) from E.coli is investigated with solid-state NMR. The aim is to gain an insight into the enzyme’s mechanism through integration of kinetic, structural and dynamic data. The biological function of DAGK is the transfer of the γ-phosphate group from Mg*ATP to diacylglycerol (DAG) building phosphatidic acid (PA)[6] as port of the membrane-derived oligosaccharide cycle[31,34]. Surprisingly, DAGK does not share structural or sequential similarities with other kinases[12]. Typical sequence motives found in other kinases, which catalyze phosphoryl transfer reactions, are not found[13]. In its physiological form DAGK is a homo-trimer with nine transmembrane helices, three catalytic centers and a size of 39.6 kDa.
First, the set-up of a real-time 31P MAS NMR experiment is shown. This experiment allows measuring in real-time the simultaneous ATP hydrolysis in the aqueous phase and lipid substrate phos-phorylation in the membrane phase with atomic resolution under magic angle spinning[56]. After fast transfer of the sample into the NMR spectrometer the enzymatic reaction is started with a temperature jump. This approach of real-time MAS NMR in a dual-phase system was demonstrated for the lipid substrate analogs dioleoyl- (DOG) and dibutyrylglycerol (DBG), with a C8 and C4 aliphatic chain, respectively. The combination of 31P direct and cross polarization functions as a dynamic filter. In the 31P direct polarized experiment nuclei in both phases are detected, while in the 31P cross polar-ized experiment, only nuclei in the membrane phase are detected. Rates for substrate turnover, i.e. degradation of γP-, βP, αP-ATP and build-up of βP-, αP-ADP, free phosphate as side reaction, and PA are obtained, which reveal a Michaelis-Menten behavior with regard to Mg*ATP and DBG. Here Mg*ATP and DBG follow a random-equilibrium model, where every substrate can bind indepen-dently from the other substrate. Analyses of the peak integrals from educts and products of the enzymatic reaction, revealed the stoichiometry of the reaction: 1.5 ATP molecules are used to phos-phorylate one DBG molecule. The excess of ATP is attributed to the basal ATPase activity. Further-more, experiments with ATPγS, usually regarded as a non-hydrolysable ATP-analog, where carried out. Surprisingly, DAGK hydrolyzes ATPγS and also transfers the thio-phosphate group to the lipid acceptor DBG, which points to a certain degree of plasticity in the active center. A phosphorylated enzyme intermediate was not detected. These results suggest the building of a ternary complex of Mg*ATP, DBG and DAGK performing a direct-phosphoryl transfer reaction, without passing through a phosphorylated enzyme intermediate. Experiments with the transition state analog ortho-vanadate (Vi) showed a decoupling of the ATP hydrolysis activity from lipid substrate phosphorylation. This indicates a specific transfer site for the γ-phosphate group from ATP to DAG, which can be blocked by Vi.
A general disadvantage of NMR spectroscopy compared to other spectroscopic methods is its inherent low sensitivity. One possible starting point for the improvement of signal-to-noise per unit time is the reduction of the spin-lattice relaxation time of protons[209]. Usually 95 % of the experi-mental time is required for the relaxation of the 1H to equilibrium. The addition of paramagnetic species can be used to reduce the 1H T1[233]. In a comprehensive study four different paramagnetic agents were tested: Cu2+-EDTA, Cu2+-EDTA-tag, Gd3+-TTAHA and Gd3+-DOTA. The titration of these paramagnetic complexes showed the principle feasibility of this approach, but differences between the tested species exist. The most promising complex is Gd3+-DOTA which, at a concentration of 2 mM, causes a 10-time improvement of signal-to-noise ratio per unit time. This allowed measuring 2D 13C-13C correlation spectra of proteoliposomes in one tenth of the usual required experimental time (i.e. 10 hours vs. 4 days) with good signal-to-noise.
For the investigation of structural or dynamic changes in the protein upon substrate interaction with MAS NMR, the spectral properties CP efficiency and resolution of the DAGK in liposomes needed to be improved. The most critical step during sample preparation is the reconstitution of the membrane protein from detergent micelles into a membrane of synthetic lipids under detergent removal. For this procedure the important criteria are enzymatic activity, measured in a coupled ATPase assay[55], and homogeneity of the proteoliposomes, which was tested e.g. on a discontinuous sucrose step gradient. Therefore an extensive study was carried out, in which different detergents, lipids and lipid mixtures, techniques for detergent removal and different protein-to-lipid ratios were tested. A direct correlation between high ATPase activity and good resolution was not found. Moreover, active DAGK in a mixture of DMPC and cholesterol, which emulates the membrane features of a membrane containing DAG, showed the best CP efficiency and resolution.
The assignment of the protein backbone and amino acid side chains the first mandatory step towards the investigation of structural and dynamical features influencing and defining the enzymatic mechanism by MAS NMR. As the assignment procedure is very time consuming for a total protein, a special labeling scheme for DAGK was developed, which allows assigning most of the protein areas presumably involved in enzyme catalysis. The assignment of DAGK with solution NMR[132] was not transferable to the MAS NMR spectra. Most important for the assignment process were the unique pairs[335], two consecutive amino acids which only appear once in the amino acid sequence. These unique pairs served as anchor points. Five different multinuclear MAS NMR experiments (DARR, NCO, NCA, NCACX, NCOCX) were required for the sequential assignment. It was possible to assign 35 % of the total amino acid sequence with one sample and 8 experiments acquired at 850 MHz. The secondary structure analysis showed subtle differences to the DAGK assignment with solution NMR[132], which can be attributed to the different environment in lipid bilayers and detergent micelles.
Data about structural and dynamical changes under substrate interaction can reveal details about the enzymatic mechanism. Therefore changes in chemical shift in 2D heteronuclear correlation experiments in the apo-state and under substrate saturated conditions with the substrates Mg*AMP-PNP, a non-hydrolysable ATP-analog, DOG, a mixture of Mg*AMP-PNP and DOG as well as inhibited by Vi were recorded. The most significant peak changes were observed at the interface membrane-cytoplasm as well as the the N-terminal amphipathic helix. The residues revealing chemical shift perturbations correlate with conserved residues or such residues, for which importance for catalysis and/or folding could be shown in mutation studies[8]. Especially noticeable were the changes at the amino acids Asn 72, Lys 64, His 87, Tyr 86 and Asp 95.
Beside changes of the chemical shift, changes of line width or signal doubling were observable. These changes can point to a correlation with dynamic reorientations in the μs-ms time regime, which are most relevant for enzymatic processes. The protein backbone dynamics in the apo-state as well as saturated with the substrates or inhibited with Vi were investigated with a 15N-CODEX experiment, which is based on the reorientation of the CSA tensor upon dynamical changes[350]. Specific effects of the different substrates or analogs on the protein backbone dynamic were revealed complementing the structural data and the chemical shift perturbation experiments.
Nichtribosomale Peptid Synthetasen sind Quelle für eine Vielzahl an Sekundärmetaboliten mit antibiotischer Wirkung. Jede Synthetase besteht aus einer Abfolge von Modulen, wobei jedes Modul die nötigen Domänen für den Einbau eines Bausteins in das gebildeten Peptids enthält. Ein Ansatz zur Gewinnung neuer Peptidantibiotika, die angesichts der steigenden Zahl multiresistenter Keime dringend benötigt werden, ist der Austausch von Domänen oder Modulen. Aufgrund bisher noch nicht verstandener Selektivitäten, entweder zwischen den Domänen oder zwischen einzelnen Domänen und Zwischenstufen des gebildeten Peptids, führt dieser Ansatz jedoch in der Praxis oft zu keiner oder nur geringer Ausbeute.
Ziel der vorgelegten Arbeit war es, einige dieser Selektivitäten zu untersuchen, wobei der Fokus auf Peptidyl Carrier Proteinen Domänen (PCPs) lag. An diese Domänen sind alle Intermediate während der Reifung des Peptids kovalent über einen Phosphopantethein-Kofaktor (Ppan-Arm) gebunden.
Im ersten Teil der Arbeit sollte die Struktur einer mit einem Heptapeptid beladenen PCP mittels Lösungs-Kernspinresonanzspektroskopie (NMR) bestimmt werden. Hierbei konnte die natürliche Verknüpfung zwischen Ppan-Arm und Peptid über einen Thioester nicht verwendet werden, da diese Bindung zu Hydrolyse-anfällig war. Es konnte jedoch gezeigt werden, dass die Substitution des Thioesters durch eine nicht hydrolysierbare Amidbindung keinen Einfluss auf die Struktur hat, wodurch die Strukturbestimmung möglich war. Hierbei zeigte sich, dass die Peptid-beladene PCP in der sogenannten A/H state Konformation vorliegt, wobei das an sie gebundene Peptid frei beweglich ist. Somit scheint es wahrscheinlich, dass die PCP keine Selektivität für das an sie gebundene Peptid aufweist. Dies ist ein Unterschied zu den strukturell ähnlichen Acyl Carrier Proteinen (ACPs) aus der bakteriellen Fettsäurebiosynthese, da diese eine Bindungstasche für die an sie gebundenen Fettsäuren ausbilden.
Untersuchungen der Selektivität der Kondensationsdomäne (C Domäne) für das PCP gebundene Peptid mittels NMR-Titrationen und biochemischer Analysen konnten nicht durchgeführt werden, da sich im Laufe des Projekts zeigte, dass die aus der Synthetase herausgetrennte C Domäne katalytisch nicht aktiv war. Stattdessen sollte die Kristallstruktur einer Peptid-beladenen PCP-C Bidomäne, für welche eine katalytische Aktivität bereits gezeigt worden war, gelöst werden. Da aber bereits ein signifikanter Anteil der Bidomäne während der Expression mit dem Ppan-Arm beladen wurde, war die nötige quantitative Beladung mit dem Peptid gekoppelten Ppan-Arm in vitro nicht möglich. Eine quantitative Modifizierung mit dem Ppan-Arm in vitro war hingegen erfolgreich, und die Struktur der Ppan-beladenen Bidomäne konnte gelöst werden. Aufgrund des großen Abstands zwischen den aktiven Zentren der beiden Domänen kann es sich bei der beobachteten Orientierung nicht um jene handeln, die die beiden Domänen zueinander annehmen, wenn die C Domäne das PCP-gebundene Peptid bindet.
Im zweiten Teil der Arbeit wurde die Modifizierung einer PCP durch eine Gruppe II Phosphopantetheintransferase (PPT) untersucht. PPTs katalysieren die Übertragung des Ppan Arms auf die Seitenkette eines in PCPs konservierten Serins. In dieser Magnesium-abhängigen Reaktion dient Coenzym A (CoA) als Quelle für den Ppan-Arm. Durch Mutation des konservierten Serins in der PCP zu Alanin konnte ein stabiler Komplex aus PCP und PPT in Anwesenheit von CoA und Magnesium kristallisiert und seine Struktur bestimmt werden.
In einem Strukturmodell für den PCP/PPT Komplex war eine andere Konformation für die PCP postuliert worden, als sie in der Kristallstruktur des Komplexes zu beobachten ist. Durch Strukturbestimmung der PCP mittels Lösungs-NMR und anschließender Titrationsexperimente konnte jedoch gezeigt werden, dass sowohl die freie als auch die komplexierte PCP in Lösung ebenfalls die in der Kristallstruktur beobachtete Konformation einnehmen.
Aufgrund der gelösten Kristallstruktur konnten zwei Bereiche identifiziert werden, in denen die beiden Proteine im Komplex in direktem Kontakt zueinander stehen. Der eine Bereich ist durch eine intermolekulare Wasserstoffbrücke, der andere durch hydrophobe Wechselwirkungen zwischen den Proteinen gekennzeichnet. Durch ortsspezifische Mutagenese konnten beide Wechselwirkungen gestört werden, was sich in einer Abnahme der Komplexstabilität und einer veränderten Geschwindigkeit der Übertragung des Ppan-Arms äußerte.
Die große strukturelle Ähnlichkeit zwischen dem in dieser Arbeit untersuchten Komplex aus zwei in Bacillus vorkommenden Proteinen und einem humanen ACP/PPT Komplex legt die Vermutung nahe, dass die beobachteten Wechselwirkungen in vielen Organismen konserviert sind.
5-LO is the key enzyme in the biosynthesis of proinflammatory leukotrienes. It catalyses the conversion of arachidonic acid to the hydroperoxy intermediate 5(S)-hydroperoxy-6- trans-8,11,14-cis-eicosatetraenoic acid (5-HpETE). In a second step 5-LO catalyses a dehydration reaction forming the unstable epoxide intermediate 5(S)-trans-5,6-oxido-7,9- trans-11,14-cis-eicosatetraenoic acid (leukotriene A4 , LTA4). The 5-LO gene is subjected to versatile regulation mechanisms. Apart from regulation by DNA-methylation and histone acetylation / deacetylation 5-LO gene expression can be regulated by the differentiation inducers calcitriol (1,25-dihydroxyvitamin D3) and transforming growth factor beta (TGFβ) 5-LO gene expression. In the myeloid cell lines Mono Mac 6 (MM6) and HL-60, differentiation with both agents caused a prominent upregulation of 5-LO mRNA level, of 5-LO protein expression and of 5-LO activity. Treatment with calcitriol alone already has an impact on 5-LO gene expression which is additionally potentiated by TGFβ treatment. Previous nuclear run-off analysis and reporter gene analysis could not associate the 5-LO promoter with the induction of 5-LO mRNA expression mediated by calcitriol and TGFβ. Inclusion of the 5-LO coding sequence (cds) and inclusion of the 5-LO cds plus the last four introns of the gene (J to M) in the 5-LO promoter construct pN10 led to an enhanced reporter gene activity. The inductions were dependent on vitamin D receptor (VDR) and retinoid x receptor (RXR) cotransfection. Therefore the work was concentrated on identifying elements outside the 5-LO promoter region which contribute to the calcitriol / TGFβ effect on 5-LO mRNA expression. Insertion of the LTA4 hydrolase coding sequence – a coding sequence of similar size - instead of the 5-LO cds led to a loss of the calcitriol / TGFβ effect (pN10LTA4Hcds 1-fold induction). Therewith, it was proven that the presence of the 5-LO cds is crucial for the upregulating effect of calcitriol / TGFβ on 5-LO mRNA level. Cloning of the SV40 promoter instead of pN10 upstream of the 5-LO cds still showed inducibility by treatment with the inducers which argues for a promoter unspecific effect. Insertion of the 5-LO cds in a promoterless basic vector (pGL3cds) displayed same inductions by calcitriol / TGFβ treatment as the 5-LO promoter 5-LO cds construct (pN10cds). Thus, the effect of the inducers is not dependent on the 5-LO promoter under the in vitro conditions of the reporter gene assay. Hence, further cloning was done with promoterless constructs. Through 5-LO cds deletion constructs a positive regulating region in exon 10 to 14 was discovered. To adapt the natural gene context the last four introns (J-M) of the 5-LO gene were inserted in a promoterless construct containing exon 10 to 14 (pGL3cdsΔABInJM). 5end deletion constructs of it revealed putative vitamin D responsive elements (VDREs) in exon 12 and intron M. Mutation of the putative VDREs led to a reduced calcitriol effect –more prominent when the putative VDRE in intron M was mutated (reduction of 40%). Moreover another putative VDRE in exon 10 with an adjacent SMAD binding element (SBE) was detected. SMAD proteins are effector proteins of TGFβ signalling. Gelshift experiments demonstrated in vitro binding of the VDR-RXR heterodimer to those three putative VDREs. By chromatin immunoprecipitation (ChIP) assay in vivo binding of VDR and RXR was shown to the VDRE in the region of exon 10, exon 12 and intron M. 8h and 24h incubation with calcitriol / TGFβ resulted in enhanced expression of VDR in each of the examined regions. The VDR is able to bind to the VDRE without its ligand, whereas this goes along with corepressor recruitment and thus the VDR has a repressive effect on transcription. Histone H4 acetylation was increased when MM6 cells were treated for 8h or 24h with calcitriol or the combination of calcitriol / TGFβ. This finding implies that at that point of time corepressors associated with the VDR are replaced by coactivators. It seems convincing that 5-LO transcription is mainly promoted by calcitriol alone which leads to a more accessible chromatin structure. Previous data indicated that calcitriol and TGFβ upregulate 5-LO RNA maturation and 5- LO transcript elongation. Thus several elongation markers were investigated by ChIP analysis: Histone H3 lysine 36 (H3K36) trimethylation and H4K20 monomethylation were detected in the analysed regions in exon 10, exon 12 and intron M. In region exon 10 the H3K36 trimethylation status was enhanced after 24h calcitriol or calcitriol / TGFβ treatment. An increased H4K20 monomethylation status in all regions was observed when MM6 cells were treated for 24h with calcitriol / TGFβ. 24h treatment with both agents also enhanced the recruitment of the elongation form of RNA polymerase II, which is phosphorylated at serine 2 of the carboxyterminal domain, to the investigated regions. These findings prove the positive regulating role for calcitriol and TGFβ on 5-LO transcript elongation. A putative mechanism of the effect of calcitriol and TGFβ on 5-LO RNA maturation might be the elevated phosphorylation of serine 2 of the RNA Polymerase II which is known to be followed by recruiting polyadenylating factors.
The multistep-processes leading to the formation of tumors have been extensively studied in the past decades, leading to the identification of “hallmarks of cancer”. They are characteristic changes in biological processes that discriminate tumor cells from healthy cells. Increasing knowledge on the molecular structures associated with tumorigenesis allowed their specific inhibition in targeted anti-cancer therapy. However, successful targeted anti-cancer therapy is only available for a limited subset of diseases, so the continuous investigation of tumorigenic mechanisms is required to tackle the immense diversity of neoplastic entities.
AVEN and FUSE binding protein 1 (FUBP1) display the ability to regulate apoptosis and cell cycle progression. Thus, the proteins are associated with hallmarks of cancer (resisting cell death and uncontrolled proliferation). Indeed, aberrant expression of AVEN and FUBP1 could be demonstrated in multiple cancers. In contrast, there is only little knowledge on the physiological function of AVEN and FUBP1. The lack of knowledge results in part from the embryonic lethality of the homozygous knockout of Aven and Fubp1 in mouse models, limiting the gain of information by analyzing these animals.
In this study, I generated conditional Aven and Fubp1 knockout mice to investigate their physiological function.
By analyzing reporter mice expressing β-galactosidase under the control of the endogenous Aven promoter, I identified Aven promoter activity to be both tissue- and cell type-specific and dependent on the developmental stage. Detecting apoptotic cell death by immunohistochemistry did not reveal increased apoptosis in Aven knockout mice, suggesting a functional role of AVEN besides apoptosis inhibition during embryogenesis.
Basing on the significant Aven promoter activity detected in the adult brain and in the mammary gland, I generated and characterized conditional Aven knockout mice with Aven deletion restricted to cells within the brain or the mammary gland. AVEN depletion in these tissues was not embryonic lethal and the affected tissues displayed a normal histology.
Since aberrant Aven expression had been associated with hematologic malignancies, I also analyzed mice with an Aven knockout in the hematopoietic system. Depletion of AVEN in the blood cells had no effect on hematopoietic stem and progenitor cell frequencies. Consequently, AVEN seems to be dispensable for the maintenance and differentiation of stem, progenitor and mature blood cells, at least as far as the expression of particular differentiation markers was concerned.
As loss of AVEN in the analyzed tissues did not affect the viability of mice and did not produce any other obvious phenotype, the exact role of AVEN that is essential for embryo survival remains to be identified.
To study the oncogenic potential of AVEN, I investigated the role of AVEN in a mouse model for breast carcinogenesis. While AVEN expression seemed to be increased in breast tumors, tumor onset and progression were not altered in mice with depleted AVEN expression in the mammary gland. Consistently, Aven knockout tumor cells were neither less proliferative nor more prone to undergo apoptosis than Aven wildtype tumor cells. Cell culture experiments demonstrated that AVEN expression is upregulated by estrogen. Knockdown of AVEN in the breast cancer cell line MCF-7 slightly increased UV irradiation-induced apoptosis and accelerated metabolism. So while AVEN does not promote development or progression of breast tumors, enhanced AVEN expression in ER+ breast cancers might contribute to chemotherapy resistance.
To study the physiological role of FUBP1, I generated a conditional Fubp1 knockout mouse model. While the insertion of loxP sites into the Fubp1 locus was occasionally embryonic lethal, some mice with a cell type-specific deletion of Fubp1 in hematopoietic cells or EPO receptor expressing cells were born alive. In these mice, frequencies of hematopoietic stem and progenitor cells as well as erythrocytes were unaltered. These results conflict with previous publications. However, compensating mechanisms might be responsible for the discrepancies between the observed phenotypes and reported FUBP1 function.
In cell culture studies, I could demonstrate that the previously reported upstream regulation of FUBP1 by TAL1 depended on an intact GATA motif in the FUBP1 promoter and that binding of GATA1 to the FUBP1 promoter increased during erythropoiesis.
To identify new FUBP1 target genes with relevance for erythropoiesis, I performed differential gene expression analysis in cells with wildtype and depleted FUBP1 expression. RNA-sequencing and PCR-arrays revealed only moderate differences in the expression of genes that are components of the EPO receptor signaling pathway as well as genes associated with apoptosis and proliferation of hematopoietic cells. By regulating the transcription of these genes, FUBP1 could contribute to efficient erythropoiesis.
Membrane proteins are biological macromolecules that are located in a cell’s membrane and are responsible for essential functions within an organism, which makes them to prominent drug targets. The extraction of membrane proteins from the hydrophobic membrane bilayer to determine high-resolution crystal structures is a difficult task and only 2% of all solved proteins structures are membrane proteins. Computational methods may help to gain deeper insights into membrane protein structures and their functions. This study will give an overview of such computational methods on a representative set of membrane proteins and will provide ideas for future computational and experimental research on membrane proteins.
In a first step (chapter 2), I updated an earlier, manually-curated data set of homologous membrane proteins (HOMEP) to more recent versions in 2010 (HOMEP2) and 2013 (HOMEP3) using an automated clustering approach. High-resolution structures of membrane proteins listed in the PDB_TM database were structurally aligned and subsequently clustered using structural similarity scores. Both data sets were used as a standard gold reference set for subsequent work.
Subsequently, I have updated and applied the sequence alignment program AlignMe to determine protein descriptors that are suitable for detecting evolutionary relationship between homologous a-helical membrane proteins. Single input descriptors were tested alone and in combination with each other in different modes of AlignMe by optimizing gap penalties on the HOMEP2 data set. Most accurate alignments and homology models on the HOMEP2 data set were observed when using position-specific substitution information (P), secondary structure propensities (S) and transmembrane propensities (T) in the AlignMe PST mode. An evaluation on an independent reference set of membrane protein sequence alignments from the BAliBASE collection showed that different modes of AlignMe are suitable for different sequence similarity levels. The AlignMe PST mode improved the alignment accuracy significantly for distantly related proteins, whereas for closely-related proteins from the BAliBASE set the AlignMe PS mode was more suitable. This work was published in March 2013 in PLOS ONE. In order to allow also an easier usage of the AlignMe program, I have implemented a web server of AlignMe (chapter 4) that provides the optimized settings and gap penalties for the AlignMe P, PS and PST modes. A comparison to other recent alignment web server shows that the alignments of AlignMe are similar or even more accurate than those of other methods, especially for very distantly related proteins for which the inclusion of membrane protein information has been shown to be suitable. This work was published in the NAR web server issue in July 2014.
Although membrane-specific information has been shown to be suitable for aligning distantly related membrane proteins on a sequence level, such information was not incorporated into structural alignment programs making it unclear which method is the most suitable for aligning membrane proteins. Thus, I compared 13 widely-used pairwise structural alignment methods on an updated reference set of homologous membrane protein structures (HOMEP3) and evaluated their accuracy by building models based on the underlying sequence alignments and used scoring functions (e.g., AL4 or CAD-score) to rate the model accuracy (chapter 5). The analysis showed that fragment-based approaches such as FR-TM-align are the most useful for aligning structures of membrane proteins that have undergone large conformational changes whereas rigid approaches were more suitable for proteins that were solved in the same or a similar state. However, no method showed a significant higher accuracy than any other. Additionally, all methods lack a measure to rate the reliability of the accuracy for a specific position within a structure alignment. In order to solve these problems, I propose a consensus-type approach that combines alignments from four different methods, namely FR-TM-align, DaliLite, MATT and FATCAT and assigns a confidence value to each position of the alignment that describes the agreement between the methods. This work has been published 2015 in the journal “PROTEINS: structure, function and bioinformatics”.
Consensus alignments were then generated for each pair of proteins of the HOMEP3 data set and subsequently analyzed for single evolutionary events within membrane spanning segments and for irregular structures (e.g., 310- and p-helices) (chapter 6). Interestingly, single insertions and deletions could be observed with the help of consensus alignments in the conserved membrane-spanning segments of membrane proteins in four protein families. The detection of such single InDels might help to identify crucial residues for a proteins function.