Refine
Year of publication
Document Type
- Doctoral Thesis (44)
Language
- English (44) (remove)
Has Fulltext
- yes (44)
Is part of the Bibliography
- no (44)
Keywords
- Molekülstruktur (2)
- rhodopsin (2)
- solid-state NMR (2)
- Ackerschmalwand (1)
- Arzneimitteldesingn (1)
- Arzneimittelentwicklung (1)
- Azide (1)
- C. elegans (1)
- DNP (1)
- Detergenz (1)
Institute
- Biochemie und Chemie (25)
- Biochemie, Chemie und Pharmazie (16)
- Biowissenschaften (1)
- Pharmazie (1)
- Physik (1)
Fokus meiner Doktorarbeit ist die Anwendung und Entwicklung NMR-spektroskopischer Methoden zur Charakterisierung zeitabhängiger Strukturänderungen von Biomolekülen – von lokalen dynamischen Veränderungen bis zur vollständigen Rückfaltung von Proteinen – und fasst die Ergebnisse meiner drei wichtigsten PhD-Projekte zusammen.
In meinem ersten Projekt habe ich die Leistung eines Temperatursprung-Probenkopfs – mit dem Proben mit hoher Salzkonzentration schnell erwärmt werden können – mithilfe einer Hochfrequenzspule technisch optimiert. Die optimierten Radiofrequenz-Bestrahlungsparameter, Lösungsmittel-bedingungen und der reduzierte Arbeitszyklus führten zu einem Temperatursprung von 20 °C in 400 ms. Ich habe eine Cystein-freie Mutante von Barstar hergestellt, die nach Zugabe von Harnstoff bei 0 °C kalt denaturiert werden kann, während sie ihren gefalteten Zustand bei 30 °C hält. Dadurch wurde auch ermöglicht, dass der Rückfaltungsprozess hunderte Male ohne Abbau oder Aggregation wiederholt werden kann. Die Kombination von reversibler Rückfaltung und rascher Temperaturänderung des kalt denaturierten Barstars ermöglichte die Entwicklung eines neuen kinetischen Experiments, bei dem der Rückfaltungsprozess von Barstar mit einem zweidimensionalen Echtzeit-NMR in hoher Zeitauflösung untersucht wird. Die vollständige Rückgratresonanzzuweisung wurde sowohl für den gefalteten als auch für den kalt denaturierten Zustand von Barstar durchgeführt und ergab, dass in der denaturierten Form beide Prolin-Reste einen gemischten Konformationszustand aufweisen. Dabei befindet sich die Tyr47-Pro48-Amidbindung im ungefalteten Zustand hauptsächlich in trans-, während im gefalteten Zustand in der seltenen cis-Konformation. Das neue hochauflösende kinetische Experiment zeigte, dass die Rückfaltung von Barstar durch die trans-cis-Isomerisierung der Tyr47-Pro48-Amidbindung verlangsamt wird, was sowohl die Sekundärstruktur als auch die Bildung der Tertiärstruktur beeinflusst. Basierend auf diesen Ergebnissen konnte ich einen plausiblen Faltungsmechanismus für den langsamen Faltungsweg von kalt denaturiertem Barstar skizzieren. Durch Änderung der Zeitparameter des Heizungszyklus wurde erreicht, dass die Tyr47-Pro48-Amidbindung im ungefalteten Zustand in der cis-Konformation bleibt und daher der schnelle Faltungsweg dominant wird. Das Starten des Magnetisierungstransfers vor der Temperaturänderung ermöglichte die Aufzeichnung eines Spektrums, das den entfalteten Zustand mit dem gefalteten Zustand korreliert. Dieses Spektrum ermöglichte quantitative Analysen des schnellen Faltungsweges und lieferte sogar indirekte Hinweise auf einen Zwischenzustand. Diese Methode aus Kombination von schnellem Temperatursprung und Kaltdenaturierung zeigt ein hohes Potenzial, Proteinfaltung auf atomarer Ebene experimentell zu untersuchen und ein tieferes Verständnis verschiedener Faltungswege zu erlangen.
In meinem zweiten Projekt – das Teil einer interdisziplinären Forschung war – konzentrierte ich mich auf die NMR-spektroskopische Charakterisierung von Nukleinsäuren, die mit einer photolabilen Schutzgruppe modifiziert wurden. Zuerst wurde mithilfe homonuklearer Korrelationsexperimente eine vollständige Protonresonanzzuweisung erreicht. Danach wurde die relative Konfiguration der photolabilen Schutzgruppen bestimmt basierend auf einer dreidimensionalen Modellstruktur und spezifischer NOE-Korrelationen. Des Weiteren wurde ein Strukturmodell unter Verwendung von NOE-Einschränkungen berechnet. Dieses Strukturmodell zeigte eine eingeschränkte Rotation um die CN-Bindung zwischen dem Käfig und der Nukleobase. Das Modell zeigte auch, dass der Käfig in der Hauptrille positioniert ist und nicht in das Lösungsmittel herausklappt. Im Vergleich zu einem zuvor charakterisierten NPE-Käfig führte die erhöhte Größe zu einer weiteren Senkung des Schmelzpunkts, zeigte jedoch einen geringeren Schmelzpunktunterschied zwischen der S- und der R-Konfiguration des Käfigs, wobei die S-Konfiguration zu einer größeren Reduktion des Schmelzpunktes führt. Dieser Trend wurde weiter untersucht und durch ein Screening unterstützt. Durch selektive Wasserinversions-Rückgewinnungsexperimente konnte ich auch zeigen, dass der Käfig die lokale Stabilität nur bis zu einer Entfernung von zwei benachbarten Basenpaaren von der Modifikationsstelle verringert. Die NOE-Daten dienten auch als guter Bezugspunkt, um die Qualität molekulardynamischer Simulationen zu testen, mit denen zusätzliche Käfigdesigns untersucht wurden. Die Kombination aus Synthese, NMR-Spektroskopie und MD-Simulationen ermöglichte bis jetzt die detaillierteste Untersuchung des Effekts vom Einbau eines einzelnen Käfigs zur Destabilisierung der DNA-Sekundärstruktur. Dabei wurden Einschränkungen des möglichen Designs aufgedeckt, aber auch die Entwicklung einer neuen, effizienteren Struktur ermöglicht.
Mein drittes Projekt konzentrierte sich auf die Charakterisierung eines RNA-Modellsystems. NMR-spektroskopische Daten von kleinen RNA-Modellsystemen – wie NOE, skalare Kopplungen, kreuzkorrelierte Relaxationsraten und RDC – sind eine unschätzbare Referenz für MD-Simulationen, obwohl die Menge der verfügbaren Literaturdaten – bis jetzt – sehr begrenzt ist. ...
This doctoral thesis deals with the structural and dynamical NMR characterization of biomolecules, covering a broad range of proteins, from small peptides to large GPCRs proteins. This work consists of two projects, which are presented in chapter II and III. Chapter II is focused on the structural screening of peptides and small proteins ranging from 14 to 71 amino acids, while chapter III describes the structure and light dynamics of the disease relevant rhodopsin G90D mutant. The main method used to investigate both types of proteins is NMR spectroscopy. Both chapters comprise individual general introduction, materials and methods, results and discussion sections, and a final conclusion paragraph.
‘Chapter I: Methodological aspects of protein NMR spectroscopy’ presents an overview of different NMR methods developed for the rapid characterization of protein structure and dynamics. Multidimensional NMR, which is routinely used in structural biology, is indispensable for protein structure determination in solution. However, detailed information with resolution at the atomic level is time consuming and requires weeks of expensive measurement time, followed by the manual data analysis. Therefore, the development of time-saving NMR techniques is highly required for screening studies of a large amount of proteins, and can be also helpful for studying unstable biomolecules, as their short lifetime often restricts the experimental procedure.
This chapter covers the two main approaches to accelerate a multidimensional NMR experiment: fast-pulsing techniques that aim to reduce the duration of an individual measurement, and non-uniform sampling technique (NUS), which was developed to reduce the overall number of increments in virtual time domains. A combination of both approaches, fast-pulsing and non-uniform sampling, allows speeding up the measurement time by 2-3 orders of magnitude. Furthermore, recently developed software called TA (targeted acquisition) combines various time-saving approaches, including fast-pulsing, non-uniform sampling and targeted acquisition. Targeted acquisition algorithm records a set of multidimensional NMR spectra in semi-interleaved incremental mode. This provides the ability to monitor the quality of the recorded spectra in real-time and therefore enables the completion of the experiments after the desired quality is achieved. Using this approach will greatly reduce the measurement time without losing important structural information. The implemented automated FLYA assignment further contributes to the rapid and simplified readout of the chemical shift assignment progress of the TA program. During this doctoral dissertation, the scientific collaboration with the TA software developer Prof. Vladislav Orekhov (Sweden) took place, and resulted in the successful establishing of this new NMR technology in the Schwalbe laboratory. TA is now routinely applied in Prof. Schwalbe group for the structure elucidation of small proteins.
‘Chapter II: Rapid NMR and biophysical characterization of small proteins’ describes the structural analysis of peptides and small proteins, which were recently identified within the framework of the Priority Program (SPP 2002). Due to technical limitations in detections of small systems and strict assumptions concerning the smallest size of the gene that can be translated, small open reading frames (sORFs) were excluded from the automated gene annotation for a very long time. Thanks to the newly developed computational and experimental approaches, the ability to identify and detect the small proteins consisting of less than approximately 70 amino acids sparked a growing scientific interest by microbiologist. In the past years, hundreds of new short protein sequences were discovered. Although some peptides were found to be involved in diverse essential biological processes, the functional elucidation of a large number of recently discovered peptides and small proteins remains a challenging task. It is well established that the structure of proteins is often linked to their function. However, the size of small constructs often restricts the possible diversity of secondary structure elements that might be adopted by a protein. Furthermore, as was shown for intrinsic discorded proteins (IDPs), the absence of a well-defined three-dimensional structure does not necessarily mean lack of function. Moreover, peptides, which are initially unstructured in the isolated form can fold in a stable structured conformation upon interaction with their biological partners. Solution state NMR spectroscopy is perfectly amenable for the structural characterization of systems of this size. It provides a rapid readout about the conformational state of small peptides unambiguously, distinguishing between folded, molten globule and unstructured conformations.
During this doctoral thesis the workflow protocol for fast screening of peptides and small proteins was established and applied to 20 candidates ranging from 14 to 71 amino acids, which were identified and selected by six microbiological groups, all members of the Priority Program on small proteins (SPP2002) funded by the German research foundation (DFG). The screening protocol includes sample preparation and biochemical characterization. Peptides containing less than 30 amino acids were synthesized by solid phase synthesis (SPPS), while small proteins containing more than 30 amino acids were heterologously expressed in E. coli.
...
Uncaging approach, native membrane dynamics and lipidic cubic phases in biomolecular solid-state NMR
(2019)
It was previously shown for the Escherichia coli diacylglycerol kinase (DgkA) that enzyme-reactions at the membrane interface can be monitored by solid-state NMR. However, such studies can face problems due to limited accessibility of the active sites: Natural substrates for membrane enzymes, but also ligands for membrane proteins or lipid mediators, are either partitioning into the membrane and cannot be added easily, or if soluble exhibit accessibility restrictions, as they cannot freely pass through lipid bilayers. This situation complicates quantitative kinetic analysis of biochemical processes such as enzyme activity, ligand binding, but also oligomerization or folding reactions in the membrane or at its interface under MAS NMR conditions.
To overcome these limitations the feasibility and possible advantages of the uncaging approach as a new tool for biomolecular solid-state NMR to trigger reactions by light have been explored. DgkA’s enzymatic activity, exemplary of a biochemical process on the membrane interface, was thereby triggered in situ during MAS by light-induced release of its substrates that were rendered inactive with photolabile protecting groups. To be capable of uncaging sufficient amounts of substrate during MAS to follow the enzymatic reaction via 31P real-time NMR measurements, several illumination variants including an existing illumination setup to study retinal proteins under cryogenic conditions via DNP enhanced NMR were tested. As uncaging of micromole amounts of substrates requires a higher flux compared to initiation of a photocycle in retinal proteins, a new illumination setup was built with Bruker Biospin and Leoni Fibertech. It consists of a modified MAS probe and a suitable fiber bundle, allowing to efficiently couple light from high power LEDs into a sapphire rotor containing the sample, without disturbing the magnetic field homogeneity or sample rotation. By reducing the sample volume to the illuminated area up to 60 mM ATP were released by uncaging NPE ATP to initiate DgkA’s activity in several tested membrane mimetics. These mimetics included liposomes and bicelles, which are well established in the field of biomolecular solid state NMR as well as the optically transparent lipidic cubic phase of monoolein, widely used in membrane protein crystallography, but not yet well characterized as membrane mimetic under MAS conditions. A unique and powerful but compared to time and spatial resolution often underrepresented advantage of the uncaging approach for biophysical studies has been demonstrated by successful uncaging of a non-miscible lipid substrate to trigger DgkA’s kinase reaction: Initiation of processes that cannot easily be triggered by mixing. Examples of these are reactions involving highly hydrophobic, membrane partitioning compounds including lipid substrates, ligands or interaction partners, but also oligomerization or folding of biomacromolecules. The herein performed experiments therefore serve as a first demonstration of the uncaging approach’s feasibility and compatibility with a wide variety of membrane mimetics and give a first indication of its potential for a variety of biomolecular solid state NMR experiments.
As high accessibility for solutes has been a second focus for the choice of membrane mimetics, DgkA’s activity in the lipidic cubic phases of monoacylglycerols with its two continuous networks of water channels has been further characterized. Kinetic parameters obtained from 31P real time solid state NMR experiments revealed that DgkA’s activity is similar to activities obtained in swollen cubic phases in a bath solution with wider water channels. Diffusion of ATP in a non swollen cubic phase was however strongly reduced compared to ATP in solution as diffusion measurements showed. Therefore, saturation of the enzyme required distinctly higher ATP concentrations. These results thereby underline the advantage of a non invasive and label free method like NMR to directly gain information about enzymatic reactions of immobilized enzymes in porous materials. The obtained wealth of information from 31P real time NMR experiments and biochemical assays in different membrane mimetics in presence and absence of lipid substrates and activators also provided further insight into DgkA’s enzymatic activity. It confirms ATP binding and hydrolysis in the absence of a lipid substrate, in agreement with the proposed mode of substrate binding, and allowed to estimate the in vivo relevance of previously observed ATPase activity in liposomes.
Further exploration of the cubic phase as membrane mimetic for protein solid state NMR revealed its high stability under MAS at elevated temperatures and capacity to reconstitute sufficient amounts of DgkA. Unlike monoolein, DgkA was cross-polarizable in a cubic phase and exhibited similar dynamics compared to DgkA reconstituted into liposomes, allowing to acquire the herein shown dipolar coupling based 2D protein spectra. As lipidic cubic phases are not containing phospholipids, monoacylglycerols could be especially useful as membrane mimetics for 31P correlation spectra. Initial experiments under DNP conditions, where in liposomes line broadening causes severe overlap of phospholipid signals and unspecific cross polarization highlight this aspect.
In summary, herein reported results of the experiments performed with lipidic cubic phases demonstrate that they are robust and versatile membrane mimetics. They could be of advantage for a variety of solid-state NMR experiments where either optical transparency for efficient illumination is desired, accessibility for solutes and membrane components under MAS is required, or interference of phosphorous signals of other membrane mimetics must be avoided.
In the second chapter of this thesis 1H solid-state NMR as a label free method to probe membrane order and dynamics directly within a cellular and disease relevant context was used to observe the effects of soluble epoxide hydrolase (sEH) encoding gene knock-outs on membrane dynamics. Knock-out of the sEH encoding gene changed the overall membrane dynamics in the physiological temperature range of native membranes derived from mouse brains, making the bulk membrane more dynamic. To confirm that these effects are related to the enzymatic activity of sEH, substrates and products of sEH were added to evaluate their effects on membrane dynamics. 19,20 dihydroxydocosapentaenoic acid (DHDP), a product of sEH, partially reversed the knock out phenotype in a concentration dependent manner whereas the substrate 19,20 epoxydocosapentaenoic acid did not cause any effects. As both polyunsaturated fatty acids did not show differences in phase behavior in a simple phospholipid bilayer these results provide evidence that the previously observed concentration dependent DHDP induced relocation of cholesterol away from detergent resistant lipid raft fractions is associated with alteration of membrane dynamics. Therefore, also the effect of cholesterol removal via cyclodextrin on membrane dynamics was analyzed. Removal of cholesterol led to a similar temperature profile of wild type and knock out membranes thereby supporting the hypothesis that DHDP induced relocation of cholesterol is causing altered membrane dynamics. These alterations have been shown by the lead authors of the collaborative research project to induce relocation of various membrane proteins and are involved in the development of diabetic retinopathy. Furthermore, in this context inhibition of sEH has been shown to inhibit diabetic retinopathy and proposed as target for prevention of one of the leading causes of blindness in the developed world.
Transport mechanism of a multidrug resistance protein investigated by pulsed EPR spectroscopy
(2019)
In human several diseases result from malfunctions of ATP-binding cassette (ABC) systems, which form one of the largest transport system superfamily. Many ABC exporters contain asymmetric nucleotide-binding sites (NBSs) and some of them are inhibited by the transported substrate.1 For the active transport of diverse chemically substrates across biological membranes, ABC transport complexes use the energy of ATP binding and subsequent hydrolysis. In this thesis, the heterodimeric ABC exporter TmrAB2,3 from Thermus thermophilus, a functional homolog of the human antigen translocation complex TAP, was investigated by using pulsed electron-electron double resonance (PELDOR/DEER) spectroscopy. In the presence of ATP, TmrAB exists in an equilibrium between inward- and outward-facing conformations. This equilibrium can be modulated by changing the ATP concentration, showing asymmetric behaviour in the open-to-close equilibrium between the consensus and the degenerate NBSs. At the degenerate NBS the closed conformation is more preferred and closure of one of the NBSs is sufficient to open the periplasmic gate at the transmembrane domain (TMD).3 By determining the temperature dependence of this conformational equilibrium, the thermodynamics of the energy coupling during ATP-induced conformational changes in TmrAB were investigated. The results demonstrate that ATP-binding alone drives the global conformational switching to the outward-facing state and allows the determination of the entropy and enthalpy changes for this step. With this knowledge, the Gibbs free energy of this ATP induced transition was calculated. Furthermore, an excess of substrate, meaning trans-inhibition of the transporter is resulting mechanistically in a reverse transition from the outward-facing state to an occluded conformation predominantly.3 This work unravels the central role of the reversible conformational equilibrium in the function and regulation of an ABC exporter. For the first time it is shown that the conformational thermodynamics of a large membrane protein complex can be investigated. The presented experiments give new possibilities to investigate other related medically important transporters with asymmetric NBSs or other similar protein complexes.
The focus of this thesis is the integral membrane protein Escherichia coli diacylglycerol kinase (DGK). It is located within the inner membrane, where it catalyzes the ATP-dependent phosphorylation of diacylglycerol (DAG) to phosphatic acid (PA). DGK is a unique enzyme, which does not share any sequence homology with typical kinases. In spite of its small size, it exhibits a notable complexity in structure and function. The aim of this thesis is the investigation of DGK’s structure and function at an atomic level directly within the native-like lipid bilayer using MAS NMR. This way, a deeper understanding of DGK’s catalytic mechanism should be obtained.
First, the preparation of DGK was optimized, leading to a sample, which provides well-resolved MAS NMR spectra. The high quality MAS NMR spectra formed the foundation for the second step, the resonance assignment of DGK’s backbone and side chains. The assignment was performed at high magnetic field (1H frequency 850 MHz). The sequential assignment of immobile domains was carried out using dipolar coupling based 3D experiments, NCACX, NCOCX and CONCA. The measurement time could be reduced by paramagnetic doping with Gd3+-DOTA in combination with an E-free probehead. The sequential assignment was mainly performed using a uniformly labelled sample (U-13C,15N-DGK). Residual ambiguities could be resolved by reverse labelling (U-13C,15N-DGK-I,L,V). Resonances could be assigned for 82% of the residues, from which 74% were completely assigned. For validation, ssFLYA was applied, which is a generally applicable algorithm for the automatic assignment of protein solid state NMR spectra. Its principal applicability for demanding systems as membrane proteins could be proven for the first time. Overall, ~90% of the manually obtained assignments could be confirmed by ssFLYA. For the completion of DGK’s assignment, J-coupling based 2D experiments, 1H-13C/15N HETCOR and 13C-13C TOBSY, were carried out to detect highly mobile residues. This way, residues of the two termini and the cytosolic loop, which were not detectable by dipolar coupling based experiments, could be assigned tentatively. Whereupon, peaks for arginine and lysine were assigned unambiguously to Arg9 and Lys12. Overall, ~84% of the residues could be assigned by the applied NMR strategy. Furthermore, a secondary structure analysis was carried out. It showed substantial similarities between wild-type DGK, its thermostable mutant determined both by MAS NMR and the crystal structure of wtDGK. However, there are few differences around the flexible regions most likely caused by the high mobility of these regions. During the assignment procedure, no systematic peak doublets or triplets were detected, indicating that the DGK trimer adopts a symmetric conformation. This is in contrast to the X-ray structure, which shows asymmetries between the three subunits. Especially, crystal packing may be a potential source for these structural asymmetries.
On the basis of the nearly complete assignment of DGK, the apo state was compared with the substrate bound states. Perturbations in peak position and intensity of the substrate bound states were analysed for all assigned residues in 3D and 2D spectra. The nucleotide-bound state was emulated by adenylylmethylenediphosphonate (AMP-PCP), a non-hydrolysable ATP analogue, whereas the DAG-bound state was mimicked by 1,2-dioctanoyl-sn-glycerol (DOG, chain length n = 8). Upon nucleotide binding, extensive chemical shift perturbations could be observed. These data provide evidence for a symmetric DGK trimer with all of its three active sites concurrently occupied. Additionally, it could be demonstrated that the nucleotide substrate induces a substantial conformational change. This most likely supports the enzyme in binding of the lipid substrate, indicating positive heteroallostery. In contrast, the overall alterations caused by DOG are very minor. They involve mainly changes in peak intensities. For DGK bound with either AMP-PCP+DOG or only AMP-PCP, a similar spectral fingerprint was observed. This implies that binding of the nucleotide seems to set the enzyme into a catalytic active state, triggering the actual phosphoryl transfer reaction.
The investigation of DGK’s remarkable stability and the cross-talk between its subunits forms the last part of this thesis. This demands for the identification of key intra- and interprotomer contacts, which are of structural or functional importance. For this purpose, 13C-13C DARR and 2D NCOCX spectra with long mixing times were recorded using high field MAS NMR. Additionally, DNP-enhanced 13C−15N TEDOR experiments were conducted on mixed labelled DGK trimers to enable the visualization of interprotomer contacts. With the applied NMR strategy, intra- (Arg32 - Trp25/ Glu28/ Ala29 and Trp112 - Ser61) and interprotomer (ArgNn,e - AspCg/ GluCd/ AsnCg) long-range interactions could be identified.
The membrane protein Green Proteorhodopsin (GPR), found in an uncultured marine γ-proteobacterium, is a retinal binding protein and contains a conserved structure of seven transmembrane helices (A-G). The retinal is bound to a conserved lysine residue (K231) in helix G via Schiff base linkage. It belongs to the widespread family of microbial rhodopsins and functions as a light dependent outward proton pump that bacteria may utilize for establishing a proton gradient across the cellular membrane. Proton pumping takes place after photon absorption, where GPR goes through a series of conformational changes, termed photocycle, causing the proton to be transported across the cellular membrane from the intra-cellular to the extracellular space. It is further mediated by the highly conserved functional residues D97 and E108, which function as the primary proton acceptor and primary proton donor for the protonated Schiff base, respectively. Another functionally important residue is the highly conserved H75 in helix B. It forms an intra-molecular cluster with D97 and is responsible for the high pKa value of the primary proton acceptor, stabilized by a direct interaction between D97 and H75.
Different Proteorhodopsin variants are globally distributed and colour tuned to their environment, depending on the water depth in which they occur. A single residue in the retinal binding pocket at position 105 is responsible for determining the absorption wavelength of the protein. GPR (from eBAC31A08) contains a leucine at position 105, while BPR (blue proteorhodopsin, from Hot75m4) in deeper waters possesses a glutamine. Although GPR shows 79% sequence identity with BPR, a single amino acid substitution (L105Q) in GPR is able to switch the absorption maximum to the one of BPR.
Protein oligomerisation describes the association of subunits (protomers) through non-covalent interactions, forming macromolecular complexes. It is an important structural characteristic of microbial rhodopsins, contributing to structural stability and promoting tight packing of the protomers in the bacterial membrane. GPR was shown to assemble into radially arranged oligomers, mainly pentamers and hexamers. No high resolution crystal structure of the whole GPR complex is available, but the structurally related BPR (Hot75m4) was successfully crystallized, showing pentameric oligomers.
The BPR crystal structure model reveals detailed information about complex assembly of the whole proteorhodopsin family. It reveals the oligomeric structures and shows residues that are part of the protomer interfaces, forming cross-protomer contacts, which is valuable information for the elaborate analysis of cross-protomer interactions of GPR oligomers.
Based on the knowledge of GPR and BPR oligomeric complexes, the aim of this study is to analyse specific cross-protomer contacts and to characterize the functional role of GPR oligomerisation. This includes the identification of residues, which are part of charged cross-protomer contacts and play an important role for the formation of the GPR oligomeric complex. Furthermore, this study deals with a detailed characterization of a potentially functional cross-protomer triad between the residues D97-H75-W34, which was detected in the BPR structural model. Hereby, the focus lies especially on the functional role H75, which is highly conserved and is positioned in between the primary proton acceptor D97 and W34 across the protomer interface. In summary, this study addresses GPR oligomerisation via specific cross-protomer contacts and its potential role for the functional mechanism of the protein.
The fundamental technique used in this study is solid-state NMR. Furthermore, an elaborate characterization of GPR oligomerisation was executed using a variety of biochemical methods and mutational approaches. Solid-state NMR is a powerful biophysical method to analyse membrane proteins in their native lipid environment and can be used to obtain diverse information about structure, molecular dynamics and orientation of the protein in the lipid bilayer.
Solid-state NMR naturally has a low sensitivity. In order to detect the low number of spins, DNP signal enhancement is of particular importance in this study. It is exhibited under cryogenic conditions and allows to drastically enhance the solid-state NMR signal by transferring magnetization from highly polarized electrons to the nuclear spins.
By applying these methods and techniques on GPR oligomers, this study reveals new insights in specific cross-protomer interactions in the complex. First the oligomeric states of GPR were determined for the specific experimental conditions used in this study. LILBID-MS, BN-PAGE and SEC analysis identified the pentameric state to be dominant for GPR. Furthermore, specific interactions across the protomer interface, which drive GPR oligomerisation, were identified. This was conducted by creating mixed 13C-15N labelled complexes. These mixed complexes show a unique isotope labelling pattern across their protomer interfaces. Solid-state NMR 13C-15N-correlation spectroscopy (TEDOR) was used to identify through-space dipole-dipole couplings, which indicate specific cross-protomer contacts. The results indicated that the residues R51, D52, E50 and T60 are important for GPR oligomerisation, and further analysis via single mutations of these residues showed a severe impact of the GPR oligomerisation behaviour.
The functional importance of GPR oligomerisation was analysed by DNP-enhanced solid-state NMR on the cross-protomer D97-H75-W34 triad. The DNP cryogenic conditions allowed to trap GPR in distinct stages of the photocycle. It could be shown that trapping GPR in a specific intermediate leads to a drastic conformational effect for the highly conserved H75 residue. Furthermore, DNP-enhanced solid-state NMR was used to characterize the cross-protomer contact between H75 and W34. Mutations of W34 could show that the cross-protomer interaction is highly important for the functionality of the protein, as negative mutants such as W34E showed a reverse proton transport across the bacterial membrane.
In summary this study represents a detailed analysis of GPR cross-protomer interactions and sheds light into the cause and functional importance of oligomeric complex formation in the microbial rhodopsin.
Die Tumorprotein-Familie des Proteins p53 besteht aus drei Familienmitgliedern p53, p63 und p73 mit diversen Funktionen als Transkriptionsfaktoren. p53 war das erste Mitglied dieser Familie, das im Jahre 1979 entdeckt wurde und wurde zunächst als krebsverursachendes Protein eingeordnet, weil es in vielen Tumorgeweben in erhöhter Menge vorgefunden wurde. Es wurde allerdings festgestellt, dass der Großteil dieser gefundenen p53-Proteine funktionsunfähig durch Mutationen in ihrer Aminosäuresequenz waren. Unmutiertes p53 hingegen führt zu einem Stopp von Zellteilung oder sogar Zelltod, sofern die Zellen genetischem Stress durch Strahlung oder mutagene Chemikalien ausgesetzt sind. Heute wird p53 als eines der wichtigsten Tumor-Unterdrückungsproteine betrachtet. Die beiden anderen Familienmitglieder p63 und p73 existieren in einer Vielzahl von Isoformen. Neben carboxyterminaler alternativer mRNA-Prozessierung (α, β, γ, usw. Isoformen) führen zwei unabhängige Promotoren auch zu zwei unterschiedlichen Aminotermini. Hier wird zwischen ΔN- und TA-Isoformen unterschieden. Im Falle von p63 treten zwei dominante Isoformen auf, ΔNp63α und TAp63α. Während ΔNp63α eine Rolle in der Differenzierung von Haut spielt, wurde TAp63α bisher ausschließlich in Eizellen gefunden. Dort hat es die Funktion eines Sensors, der die genetische Integrität der weiblichen Keimbahn sicherstellt. Es liegt in Eizellen in hoher Konzentration vor, allerdings in einer komplett inaktiven Form. Werden Schäden im der Erbgut der Eizelle festgestellt, so wird das Protein aktiviert und kann so den Prozess des Zelltods der Eizelle einleiten. Mutationen oder das Fehlen des p63-Genes führen zu Missbildungen während der Entwicklung und zu unvollständig ausgebildeter Haut. Im Falle von p73 gibt es ebenfalls mehrere Isoformen, wobei die Funktionen und Relevanzen der einzelnen Isoformen bisher nicht komplett geklärt werden konnten. Eine p73-negative Maus hat einen diffusen Phänotyp, der sich durch niedrige Intelligenz, fast sterile Männchen und chronische bronchiale Infektion auszeichnet. Generell sind alle Mitglieder der p53-Familie tetramere Proteine und sind nur in diesem Zustand auch aktiv. Die einzige Ausnahme stellt, wie oben beschrieben, TAp63α dar, das in einem inaktiven dimeren Zustand vorliegt und nur durch Modifikation durch zwei unabhängige Kinasen aktiviert werden kann. Dabei geht es in den tetrameren Zustand über und ist daraufhin aktiv.
Alle drei Proteine haben (anhand ihrer längsten Isoform beschrieben) eine konservierte Domänenstruktur. Am Aminoterminus befindet sich zunächst die transaktivierende-Domäne (TAD), die für Interaktionen mit transkriptionellen Koaktivatioren relevant ist. Danach folgt die stark konservierte Desoxyribonukleinsäure (DNA) bindende Domäne (DBD). Sie stellt sicher, dass der Transkriptionsfaktor sequenzspezifisch an der richtigen Stelle auf die DNA bindet. Weitergehend folgt die Tetramerisierungsdomäne (TD), welche den oligomeren Zustand des Proteins herstellt. Im Falle von p53 endet das Protein an dieser Stelle, bei p63 und p73 folgen noch das Sterile-Alpha-Motiv (SAM) und die Transkription-inhibierende Domäne (TID). Die SAM Domäne wird generell als Interaktionsdomäne beschrieben, es konnte allerdings bis dato kein Interaktionspartner gefunden werden. Die TID hat einen negativen Einfluss auf die transkriptionelle Aktivität der Proteine. Im Falle von TAp63α interagiert sie zusätzlich mit der TAD um den Dimeren Zustand zu stabilisieren.
Histon Acetylasen
Die Acetylierung von Histonen ist neben deren Methylierung die wichtigste Modifikation. Sie ist essenziell für die Transkription innerhalb aller eukaryontischen Lebewesen, da sie durch die Modifikation von Histonen die DNA für die DNA-Polymerase II zugänglich macht. Es gibt insgesamt fünf verschiedene, nicht näher miteinander verwandte Familien von Histonacetylasen. Diese Studie beschäftigt sich ausschließlich mit der KAT3 Familie, bestehend aus den Proteinen p300 und CBP. Beide sind hochgradig konserviert, in gefalteten Bereichen der Proteine erreicht die Sequenzidentität fast 100%. Beide Proteine scheinen sehr ähnliche Aufgaben zu erfüllen, die jedoch nicht komplett identisch sind. Die Fehlfunktion von einem Allel von CBP führt zum Krankheitsbild des Rubinstein-Taybi-Syndrom (RTS), während ein Mangel an p300 sich in Mäusen auf das Gedächtnis auswirkt. Der komplette Verlust beider Allele eines der Proteine ist immer tödlich, genauso wie auch Verlust jeweils eines Allels bei beiden Proteinen. Insgesamt vier unabhängige Domänen in p300/CBP sind in der Lange die transaktivierende Domänen der p53-Familie zu binden. Bei zwei der Domänen handelt es sich um Zinkfinger-Proteine (Taz1 und Taz2), die anderen beiden sind kleine, ausschließlich α-helikale Domänen (Kix und IBiD).
Diese Studie beschäftigt sich mit der Lösung von Strukturen von der transaktivierenden Domäne von p63 und p73 mit der p300-Domäne Taz2. Außerdem wurden die Auswirkungen von direkten Acetylierungen von TAp63α charakterisiert und der Effekt von einem potenten p300/CBP Inhibitor auf Oozyten unter genotoxischem Stress analysiert. Zusätzlich wurde die Phosphorylierungskinetiken von Tap63α wärend der Aktivierung durch Kinasen untersucht.
...
The focus of this research was to understand the molecular mechanism that lies behind the insertion of tail-anchored membrane proteins into the ER membrane of yeast cells. State-of-art instruments such as LILBID, and Cryo-EM, combined with the introduction of direct electron detectors, were used to analyze the proteins that capture tail-anchored proteins near the ER membrane and help their releases from a chaperone, an ATPase named Get3. Get3 escorts TA proteins to the ER membrane, where both Get3 and the TA proteins interact sequentially to Get3 membrane bound receptors Get1 and Get2. Get1 and Get2 are homologs of mammalian WRB and CAML.
The native host was used to separately produce Get1, Get2, and the Get2/Get1 single chain constructs. The studies showed that when Get1 is expressed alone, Get1 does not seems to be located in the ER membrane but rather in microbodies like shape organelles (or peroxisome). Interestingly, Get1 seems to be located in the ER membrane when it is linked to Get2 as single chain construct.
The localization study of Get2/Get1 fused to GFP shows from the fluorescence intensity that Get2/Get1.GFP has a tube-like morphology or membrane-enclosed sacs (cisterna), implying that Get2/Get1 is actually targeted to the ER membrane and is likely functional. In other words, Get1 and Get2 stabilize each other in the ER membrane.
The expression of Get2/Get1 was found to be already optimum when expressed as single chain construct because the fluorescence counts did not improve when additives such as DMSO or histidine were added. However, when Get1 and Get2 are expressed separately, additives improve their protein production yield. In 1 liter culture, Get1 yield is increased by about 3 mg and Get2 by 1.8 mg. This can be explained by the space that Get1 and Get2 should occupy within the ER membrane as they must coexist with other membrane components to maintain the homeostasis of the cell. Hence, if there were no gain for single chain construct expression, it meant that Get2/Get1 was already well expressed on its own in ER membrane and has reached its optimum expression without the help of additives. The Get2/Get1 overexpression is more stable, tolerated and less toxic for the cells to express it at a high level.
DDM has proved to be the best detergent from the detergents tested to solubilize Get1, Get2, and Get2/Get1.
Thereafter, Get1, Get2 (data not shown), and Get2/Get1 were successfully purified in DDM micelles.
Furthermore, for the first time using LILBID, the actual study has shown that Get1 and Get2 are predominantly a heterotetramer (2xGet1 and 2xGet2) but higher oligomerization may exist as well.
Get3 binds to Get1 in a biphasic way with a specific strong binding of an affinity of 57 nM and the second of 740 nM nonspecific indicative of heterogeneity within the interaction between Get1 and Get3. This heterogeneity is caused by the presence of different conformation of either protein. However, in order to characterize a high-resolution structure model of a specific target one needs highly homogenous and identical molecules of the target protein or complex in solution. The homogeneity increases the chances of growing crystals during crystallography as the good homogeneity will likely generate a perfect packing of unit cells stack (also known as crystal lattice) in the three-dimensional spaces. The same truth goes for the single particles analysis Cryo-EM, especially for smaller complexes where having less or no conformation alterations of specific targets will enable the researcher to classify the particles in 2D and 3D, therefore improving the signal-to-noise-ratio that will ultimately lead to high-resolution structure determination.
Get1, Get2/Get1 and chimeric variants (tGet2/Get1, T4l.Get2/Get1, T4l.Get2.apocyte.Get1) were crystallized but none of the crystals could diffract due to heterogeneity.
This heterogeneity was not only occurring upon the binding of Get3 to its membrane receptors, but seems to be already present within the receptors themselves through possibly different conformation.
In this Ph.D. thesis, the heterogeneity of purified Get2 and Get1 as complex or individually in detergent is then, so far, the limiting factor for obtaining a high-resolution structure model of Get1 and Get2. As mentioned above, the heterogeneity observed was not due to the quality of the sample preparation but rather to the effect of different conformations that could have been native, or just because of the micelle used, as it was proven by the 3-D heterogeneity classification by Cryo-EM.
In general, crosslinking is one way to keep the integrity of protein complexes, however it appeared not to improve the sample quality when it was analyzed in micelles. Often the integrity of some membrane proteins is affected when they are solubilized and purified in detergents.
Finally, in this study, the structural map of Get2 and Get1 complex linked with chimeric protein T4 lysozyme and apocytochrome C b562RIL gene was obtained at 10 Å. However, this single chain construct has a density map corresponding to heterodimer species (one Get1 and Get2). Therefore, based on those data the tertiary structure of Get2/Get1 in micelle is poorly defined. It could be that the membrane extraction in DDM and the purification destabilizes the structure of the complex.
Infections with multidrug resistant bacterial strains like Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa or Acinetobacter baumanii that can accumulate resistance mechanisms against different groups of drugs cause increasing problems for the health care system. Multidrug efflux pumps are able to transport different classes of substances, providing a basic resistance to different antibiotics. Especially when they are overexpressed they can keep bacterial cells alive under antibiotic pressure unless other high level resistance mechanisms like expression of β-lactamases are established. One example for a clinically relevant multidrug efflux pump is the AcrAB/TolC tripartite system of E. coli, that transports a variety of different substrates, including besides antibiotics dyes, detergents, bile salts and organic compounds from the periplasm or the inner membrane out of the cell. AcrB is the inner membrane component of the protein complex that determines not only the substrate specificity of the tripartite system but energises the transport through the whole system process via proton transduction as well. TolC is the outer membrane spanning protein that forms a pore in the outer membrane enabling the system to transport drugs over the latter out of the cell. The periplasmic membrane fusion protein AcrA connects AcrB and TolC in the periplasm completing the channel from the periplasm, respective the inner membrane to the extracellular space. AcrB assembles as trimers, in asymmetric crystal structures each of the protomers adapts a different conformation designated L(oose), T(ight) and O(pen). In the protomers tunnels open up and collaps in different conformations. In the L protomer a periplasmic cleft opens up that can initially bind substrates to the periplasmic part of AcrB. In the T conformation the deep binding pocket opens that is assumed to bind substrates tightly that were bound to the access pocket before. As well in the T conformation a second pathway leading to the deep binding pocket opens that can guide substrates from a groove between transmembrane helices TM7, TM8 and TM9, the TM8 groove, that is connected with socalled tunnel 1 that ends in the deep binding pocket. In the O conformation a new tunnel opens that connects the collapsing deep binding pocket with the periplasmic space, respective the channel through the periplasmic space formed from AcrA and TolC. Substrates were cocrystallised in access and deep binding pocket verifying their role in substrate transport. In the TM8 groove in high resolution crystal structures DDM molecules were cocrystallised in L and T conformation, indicating that the AcrB substrate DDM may utilise this entrance to the deep binding pocket. The asymmetry observed in the AcrB trimers trongly suggests a peristaltic pump mechanism. The functional rotation cycle demands communication between the subunits and tight control of substrate load of protomers during the transport to optimise the ration between protons that are transduced and substrates transported. Indeed it was shown that AcrB transport mechanism is positively cooperative for some β-lactam substrates. For the communication between the subunits it was assumed that ionic interaction between ion pairs established between charged amino acids at the interfaces of protomers in different conformations are of special importance. Thus the amino acids engaged in ionic interactions, respective ion pairs D73-K131, E130-K110, D174-K110, R168, R259-E734 were substituted with non-charged amino acids pairwise and phenotypes were determined in plate dilution assays and MIC experiments. No evidence for a general, substrate independent, reduction of AcrB activity, that would be expected when the ionic residues are of special importance for AcrB function, could be found with the methods applied. Substitutions were not only combined pairwise according to the putative ion pairs but as well in combinations of R168A with D174N, E130Q and K131M. AcrB activity is reduced for the variant R168A_D174N significantly, activity decreases further for quadruple variant E130Q_K131M_ R168A_D174N. Because the reduced activity is only observed in this combination of substitutions the phenotype must result from accumulation of small effects of the single substitutions. R168A may destabilise the protomer interfaces, as its side chain is oriented in direction to the neighbouring protomer at all interfaces, enhancing substratespecific effects of substitutions E130Q, K131M, D174N that are not in all conformations oriented towards the neighbouring protomer but as well along the substrate transport pathway. Further investigations to figure out the details of the effects observed were not conducted because fluctuating expression of the variants hindered experimental procedures.
In another approach TM8 was in focus of the interest. As mentioned above it is a possible substrate entrance in the inner membrane. The linker between TM8 and the periplasmic PC2 subdomain undergoes a coil-to-helix transition when AcrB cycles through L, T and O conformations. Linking the transmembrane part of AcrB that provides the energy for the transport process via proton transduction with the periplasmic part harbouring the major part of the substrate pathway assignes TM8 and the periplasmic linker (859-876) an important role in the function of AcrB. Thus it was investigated with an alanine-scan of residues 859 to 884 and G/P respective P/G exchange followed by phenotype characterisation in growth curve and plate dilution assays of selected variants. In the phenotype determinations none of the variants, except G861P that seems to cause massive sterical restriction in an α-helical region, displayed a general, substrate independent decrease of AcrB activity. Thus it is concluded that the individual properties of amino acids in TM8 and the periplasmic linker are not of general importance for the mechanism of AcrB. The substitution of individual amino acids had impact on uptake of different substrates in plate dilution assays in a substrate dependent manner. The uptake of some substrates, like erythromycin or chloramphenicol is more affected than that of others with rhodamine 6G resistance being only reduced for the G861P variant. A relation between the PSA of substrates and reduced activity of AcrB was observed. in Substrates with higher PSA values are more affected by substitutions in TM8 or periplasmic linker, resulting in the conclusion that substrates with higher PSA are more likely to be taken up via the TM8 groove/tunnel 1 pathway than those with lower PSA values.
In dieser Arbeit wurden die Strukturen von drei Membranproteinen mittels Einzelpartikel-Kryo‑Elektronenmikroskopie (Kryo‑EM) gelöst. Bei den Membranproteinen handelt es sich um den humanen TRP-Kanal Polycystin‑2, den sekundär-aktiven Transporter BetP aus Corynebacterium glutamicum und den Rotor-Ring der N‑Typ ATPase aus Burkholderia pseudomallei.
Kanäle sind Membranproteine, die Ionen durch eine Pore über die Membran diffundieren lassen. Durch einen präzisen, kanalabhängigen Regulationsmechanismus wird die Pore nur bei Bedarf geöffnet. TRP (transient receptor potential) Kanäle sind anhand von DNA-Sequenzvergleichen identifiziert worden und kommen ausschließlich in Eukaryonten vor. In dieser Arbeit lag der Fokus auf der Strukturbestimmung des humanen TRP Kanals Polycystin‑2 (PC‑2). PC‑2 wurde in einer Studie entdeckt, in der Patienten mit der autosomal dominanten Erbkrankheit „polyzystische Nierenerkrankung“ untersucht wurden. Patienten mit dieser Krankheit tragen eine Mutation in einem der beiden Gene PKD1 oder PKD2, welche für die Proteine Polycystin‑1 und ‑2 kodieren. In dieser Arbeit wurden verschiedene Deletionsmutanten von PC‑2 hergestellt und in das Genom menschlicher HEK293 GnTI‑ Zellen inseriert. Die Zellen, die PC‑2 bzw. die Deletionskonstrukte am stärksten synthetisierten, wurden isoliert und für die rekombinante Proteinherstellung verwendet. Die Expression von PC‑2 führte zu der Entstehung von kristalloidem endoplasmatischem Retikulum. Mutationsstudien in dieser Arbeit zeigen, dass diese morphologische Veränderung durch die Akkumulation von Membranproteinen, die mit sich selbst interagieren, begünstigt wird. Weiter ist es in dieser Arbeit gelungen, PC‑2 zu reinigen und die Struktur des Proteins mit Hilfe von Einzelpartikel Kryo-EM mit einer Auflösung von 4.6 Å zu bestimmen. Die Membrandomäne von PC‑2 ist sehr ähnlich zu den bekannten TRP Kanal Strukturen. Ein Vergleich der PC‑2 Struktur mit dem offenen und geschlossenen TRPV1 Kanal legt nahe, dass PC‑2 in seiner offenen Konformation gelöst wurde.
Der sekundär aktive Transporter BetP von C. glutamicum gehört zu der Familie der BCC- (betaine-carnitine-choline) Transporter und wird durch osmotischen Schock aktiviert. Nach seiner Aktivierung importiert BetP zwei Natriumionen und ein Glycinbetain Molekül. Durch die Akkumulierung von Glycinbetain in der Zelle steigt das osmotische Potential des Zytoplasmas, was den Wasserausstrom aus der Zelle stoppt. Viele Strukturen, die BetP in unterschiedlichen Stadien des Transportprozesses zeigen, konnten bereits mittels Röntgenkristallographie gelöst werden. Allerdings ist die N‑terminale Domäne für die Kristallisation entfernt worden und die C‑terminale Domäne, die komplett aufgelöst ist, ist an einem wichtigen Kristallkontakt beteiligt. Um strukturelle Informationen über die N‑ und C‑terminale Domäne ohne Kristallisationsartefakte zu erhalten, wurde in dieser Arbeit die Struktur von BetP mittels Einzelpartikel Kryo‑EM bestimmt. Die Struktur mit einer Auflösung von 6.8 Å zeigt BetP in einem zum Zytoplasma geöffneten Zustand. Der größte Unterschied zu allen Kristallstrukturen ist die Position der C‑terminalen α‑Helix, die um ~30° rotiert ist und dadurch deutlich enger am Protein zu liegen kommt. Da BetP in Abwesenheit von aktivierenden Stoffen analysiert wurde, wird vermutet, dass es sich bei der gelösten Struktur um den inaktiven Zustand von BetP handelt.
Rotierende ATPasen sind membrangebunden Enzymkomplexe, die bei der zellulären Energieumwandlung eine entscheidende Rolle einnehmen. Sie bestehen aus einem löslichen und einem membrangebundenen Teil. Während in dem löslichen Teil der zelluläre Energieträger Adenosintriphosphat (ATP) entweder synthetisiert oder hydrolysiert wird, baut der membrangebundene Teil entweder einen Ionengradienten auf oder nutzt die Energie eines existierenden Gradienten für die ATP Synthese. Ein wesentlicher Bestandteil des membrangebundenen Teils einer rotierenden ATPase ist der Rotor-Ring. Dieser transportiert Ionen über die Membran und rotiert dabei um seine eigene Achse. In dieser Arbeit wurde eine Studie fortgesetzt, die den Rotor-Ring der N‑Typ ATPase von B. pseudomallei mittels Kryo‑EM untersuchte und zeigte, dass der Rotor-Ring aus 17 identischen Untereinheiten aufgebaut ist. Damit hat die N‑Typ ATPase das größte Ionen-zu-ATP-Verhältnis aller bisher charakterisierten ATPasen. In dieser Arbeit wurde die c17 Stöchiometrie des N‑Typ ATPase Rotor-Rings bestätigt und die Struktur mittels Kryo‑EM bestimmt. Im besonderen Fokus lag dabei der Einfluss von Detergenzien auf die Strukturbestimmung. Es konnte gezeigt werden, dass die beiden Parameter Dichte und Mizellengröße der verwendeten Detergenzien ausschlaggebend für den Erfolg der Strukturbestimmung dieses sehr kleinen Membranproteins sind.