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In the past decade, the optogenetic toolbox for the manipulation of ion currents and cNMP levels in Caenorhabditis elegans (C. elegans) expanded. However, the implemented tools for cAMP generation were soluble enzymes (euPAC, bPAC, IlaC22 k27 and PaaC) and thus they do not precisely mimic physiological cAMP signalling occurring in microdomains in close proximity to the plasma membrane. Here, cAMP is predominantly generated by membrane-bound adenylyl cyclases, that are located in microdomains together with G protein-coupled receptors (GPCRs), protein kinase A (PKA) and their targets, enabling spatially and temporal regulation of cAMP signalling. For this reason, one aim of this study was to develop and implement membrane bound photoactivatable adenylyl cyclases for the manipulation of cAMP mediated signalling in close proximity to the plasma membrane. For this purpose, the guanylyl cyclase domains of the Blastocladiella and Catenaria Cyclase Opsins (CyclOps) were mutated to adenylyl cyclases either by introducing the mutations E497K and C566D (abbreviated as (A-2x)) or by the mutations E497K, H564D, and C566T (abbreviated as (A-3x)).
To determine the nucleotide specificity switch from GTP to ATP and the extent of light-dependent cAMP generation, the engineered enzymes were expressed in body wall muscle cells of C. elegans and in vitro cNMP measurements using C. elegans extracts were performed. Here, the highest levels of light induced cAMP generation during sustained stimulation (0.5 mW/mm2; 470 nm, 15 min) were detected for the variants BeCyclOp(A-2x), YFP-BeCyclOp(A-2x), and YFP-CaCyclOp(A-2x) (39, 57, 40 nM, respectively), though they did not reach the extent produced by the soluble bPAC (142 nM). In contrast, low magnitudes of generated cAMP were measured for the versions BeCyclOp(A-3x) and CaCyclOp(A-2x) (8 and 7 nM, respectively). Importantly, no obvious residual cGMP and basal activity was ascertained for any of the engineered enzymes.
To assess their potential to trigger and modulate cAMP mediated cholinergic neurotransmission, and to evaluate the influence of cytosolic and membrane proximal optogenetic cAMP generation, the enzymes were expressed in cholinergic motor neurons and compared to the implemented soluble bPAC via locomotion behaviour analysis on solid and in liquid media. Photoactivation of BeCyclOp(A-2x), YFP-BeCyclOp(A-2x), and YFP-CaCyclOp(A-2x) caused similarly enhanced or even more potent behavioural changes (swimming and crawling) as bPAC, whereas a more rapidly decaying response was observed for the bPAC evoked effects. Moreover, an increased diversity of the behavioural output was detected for cytosolic cAMP production by bPAC, i.e. increased bending angles and a decreased body length.
Confocal fluorescence microscopy was performed to examine the expression levels of YFP-tagged enzymes in cholinergic neurons, whereas both YFP-CyclOp(A-2x)s were expressed at similar levels, but 1.4-fold lower relative to the soluble bPAC-YFP. To compare the amount of light-dependent cAMP generation bPAC and BeCyclOp(A-2x) at light conditions that match the conditions of the behavioural experiments (30 s), cAMP measurements using C. elegans extracts were performed, whereas BeCyclOp(A-2x) depicted a 4-fold lower amount of optogenetic cAMP production than the soluble bPAC.
In sum, local (membrane proximal) cAMP generation by the membrane-bound photoactivatable adenylyl cyclases may more specifically activate cAMP dependent neurotransmission of cholinergic motor neurons than cytosolic cAMP generation, i.e. an increased mobilization and priming/docking of synaptic vesicles and an increased filling of the synaptic vesicles with the neurotransmitter acetylcholine and thus an increase in locomotion behaviour.
The optogenetic toolbox for the manipulation of cGMP mediated signalling in C. elegans consisted of the natural membrane-bound BeCyclOp and the artificial soluble bPGC. The latter generates cGMP with low efficiency and slow kinetics (~0.2 cGMP s-1), whereas BeCyclOp enables the production of much larger amounts of cGMP (L/D = 5000) at a high turnover rate (~17 cGMP s-1). Thus, one aim of this thesis was to implement a tool with features in between those of BeCyclOp and bPGC. Several orthologous CyclOps were assessed by Gao et al., 2015 for light-regulated cGMP production by in vitro assays based on the measurement of the cNMP content from CyclOp containing oocyte membranes. Here, CaCyclOp showed the highest ratio of light versus dark activity (L/D = 230) after BeCyclOp, and thus was selected for characterization in C. elegans...
Die Kernspinresonanz(NMR)-Spektroskopie ist ein leistungsstarkes analytisches Werkzeug. Allerdings ist ihre Empfindlichkeit aufgrund geringer Wechselwirkungs-energie zwischen den Kernspins und dem externen Magnetfeld begrenzt. Die dynamische Kernpolarisation (DNP) erhöht DNP die Empfindlichkeit der NMR, indem sie die Polarisation von ungepaarten Elektronenspins auf die benachbarten Kernspins überträgt. In den letzten Jahrzehnten hat die DNP bei hohen Magnetfeldern erneut an Aufmerksamkeit gewonnen, bedingt durch die Verfügbarkeit leistungsstarker Gyrotron-Mikrowellen(mw)-Quellen. Jedoch wurde die Anwendung von DNP für Flüssigkeiten im Vergleich zu Festkörperproben bei niedrigen Temperaturen (≈100 K) weit weniger erforscht. Zwei Gründe können dafür hauptsächlich benennt werden. Bei hohen Magnetfeldern (entsprechend hohen mw-Frequenzen) wird die mw-Strahlung sehr stark von Flüssigkeiten absorbiert, was zu einer starken Erwärmung führt. Darüber hinaus sind die Translations- und Rotationsdynamik der Radikale und Target-Molekülen nicht schnell genug, um Spectraldichten bei den hohen mw-Frequenzen zu erzeugen, die für eine Overhauser-Effekt (OE) DNP Verstärkung benötigt werden. In dieser Arbeit wird gezeigt, Flüssigzustands-DNP bei hohen Magnetfeldern, insbesondere bei 9,4 T, mit hocheffizienten DNP-Probenköpfen möglich ist.
Der von skalaren Hyperfein-Wechselwirkung (hfWW) angetriebene OE ist für Flüssigzustands-DNP-Forschungen von besonderem Interesse, da der von der Theorie vorhergesagte Mechanismus auch bei hohen Magnetfeldern noch effizient ist. In der vorliegenden Arbeit wurde eine Methode zur Vorabprüfung potenzieller DNP-Kandidaten durch Messungen ihrer paramagnetischen NMR-Verschiebungen vorgeschlagen und untersucht. Wir beobachtete signifikante 13C-skalare OE DNP-Verstärkungen bis zu 50 bei den ausgewählten kleinen Biomolekülen, einschließlich Imidazol, Indol, verschiedene Aminosäuren und Kohlenhydraten. Das Lösungssystem wurde auch von organischen Lösungsmitteln auf Wasser erweitert.
Im Kontext von dipolarer OE DNP haben wir den Beitrag der Rotation des Radikals neben der Translationsbewegung zwischen Radikal und Target-Molekül zur OE DNP-Effizienz systematisch untersucht, indem wir verschiedene Nitroxidderivate mit unterschiedlichen Ringgeometrien und Substituenten verwendet haben. Mithilfe eines Models, das eine 'out-sphere' Translationsbewegung und eine 'inner-sphere' Rotationsbewegung des Radikal-Lösungsmittel-Komplexes enthält, konnte unsere Beobachtungen quantitativ simuliert werden. Außerdem wurde ein anderes Model untersucht, das eine Translationsbewegung mit der Rotation von Radikalen, bei denen das ungepaarte Elektron nicht im Zentrum sitzt, kombiniert.
Eine weitere neue Entdeckung in der DNP bei hohen Magnetfeldern waren der beobachtete SE (Solid-Effekt) an Lipidmolekülen mit BDPA-Radikal oberhalb der Lipidphasen-übergangstemperatur. Die neue Anwendung von SE DNP bietet einen alternativen Mechanismus zur OE DNP in Flüssigkeiten bei hohen Magnetfeldern und könnte möglicherweise auf Makromoleküle mit relativ langsamer Rotationsbewegung angewendet werden.
Wir haben zusätzliche Untersuchungen an den Lipiddoppelschichten mit Nitroxid-radikale durchgeführt, basierend auf dem beobachteten 1H DNP-Verstärkungen in einer viskosen Lipidumgebung bei 9,4 T . Durch Messung des Feldprofils wurden DNP-Verstärkungen durch OE und SE in Abhängigkeit ihrer relativen Verschiebungen von der Elektronen-Larmor-Frequenz bestimmt. Die individuelle OE DNP-Effizienzen für Protonen des Wassers, der Lipid-Cholin-Kopfgruppen oder der Lipid-Acylketten wurde bestimmt. Dadurch wird ein quantitativer Vergleich mit MD-Simulationen ermöglicht. Obwohl die von der MD-Simulationen vorhergesagten DNP Kopplungsfaktoren noch deutliche Abweichungen von den experimentellen Beobachtungen aufweisen, wird die schnelle Dynamik nahe der Elektronen-Larmor-Frequenz, die für einen erfolgreichen OE DNP Transfer erforderlich ist, von den MD-Simulationen gut erfasst.
In der Arbeit wurden auch zwei unterschiedliche Dreifachresonanz-DNP-Experimente durchgeführt. Zum einen wurde 13C OE DNP unter 1H-Entkopplung in wässriger Natriumpyruvatlösung, und zum anderen 13C-NMR von Glycin, verstärkt durch SE DNP an 1H zusammen mit einem 1H-13C INEPT-Polarisationstransfer, im Rahmen dieser Doktorarbeit durchgeführt.
G-protein-coupled receptors (GPCRs) from the largest family of receptors in the human body. They contain seven transmembrane helices. There are roughly 800-900 GPCR genes expressed in humans encoded by 4-5% of the human genome. These receptors are the most important signal transducers and play a crucial role in cell physiology and pathology, by using various extracellular stimuli to start complex intracellular signaling. GPCRs interact with a wide variety of stimuli from small molecules (photons, ions, amines) to large molecules (peptides, small proteins), and trigger downstream cascade effects by interacting with G-proteins, GPCR kinases, and ß-arrestin. Because of their crucial roles in many cellular functions, GPCRs are the most important drug targets for the pharmaceutical industry. Approximately 30% of the clinically approved drugs available in the market are against GPCRs. In this work achieved successful expression and purification of GPCRs from class-C and class-A families. Combined with biochemical experiments, DNP-ssNMR, and molecular simulation helped to decipher the mechanism of crosstalk between the allosteric modulator, and the orthosteric binding sites of the peptide receptor. The main findings and major highlights of this dissertation are outlined in the following paragraphs.
The calcium-sensing receptor (CaSR) belongs to the GPCR class-C family and contains a large extracellular domain. This receptor regulates Ca2+ homeostasis in blood and its absorption in the kidney and bone. To understand the molecular and structural mechanisms of these receptors their cDNAs were cloned into the pPICZ and pOET1 vectors to express them in Pichia pastoris and in Sf9 insect cells respectively. The CaSR was successfully expressed heterologously in Pichia pastoris and in the insect cell with high yield. The purified receptor purified in LMNG shows no aggregation in a monomeric state. Further optimization was performed to use it for cryo-EM sample preparation and structure determination. In 2nd part of the thesis, different mini G (mini Gs, mini Gi, mini Gqs, and mini Gsi) DNA constructs were made and expressed in E. coli. It's challenging to obtain active GPCR structures due to the instability of G-protein or G-protein-bound receptors. In this work, all mini-G proteins and chimera mini-G-protein-maltose binding protein (MBP) were cloned and expressed in E. coli and purified with a His-trap column with high purity.
In the last part of the thesis, to decipher the mechanism of allosteric modulation of orthosteric binding sites in the bradykinin receptor was produced and characterized in insect cells. Angiotensin I converting enzyme inhibitors (ACEIs), are very important drugs and are widely used for the treatment of hypertension, congestive heart failure, and diabetic neuropathy. These drugs target primarily the catalytic zinc center of the ACE. It has been shown that enalaprilat, a well-known ACEI, binds to a proposed zinc-binding site on hB1R and even directly activates the receptor. To obtain information on the influence of ACEIs on the receptor-peptide complex, and to have a better understanding of the molecular mechanism and structural plasticity of the bradykinin receptor and PAM, we used the three commercially available ACEIs captopril, enalaprilat, and lisinopril for our studies. An important result of this thesis is that though enalaprilat, captopril, and lisinopril all have similar functional properties in humans, each one regulates the orthosteric binding site of hB1R in a unique way. These findings provide atomic insights into the allosteric modulation of the bradykinin receptor. This study along with the effects of ACEI on the binding sites of receptors also deciphers the effects of the Zn2+ as well as the crosstalk between zinc binding sites and ACEI compounds. The binding of allosteric modulators induces distinct endogenous binding, which might aid in creating new possibilities in the pharmaceutical field.
Synaptic transmission is a fundamental process that involves the transfer of information from a presynaptic neuron to a target cell through the release of neurotransmitters. The SV cycle is a complex series of events that enables the recycling of SVs, allowing for the sustained release of neurotransmitters. This process is mediated by a variety of proteins and enzymes, and its regulation is critical for maintaining proper synaptic function. Despite extensive research efforts, many aspects of the SV cycle and the underlying synaptic proteins remain poorly understood, highlighting the need for continued investigation into this important process. During this work, multiple aspects of synaptic transmission were studied by performing
behavioural, pharmacological, optogenetic, electrophysiological and ultrastructural assays on Caenorhabditis elegans. First, the role of two proteins (ERP-1 and RIMB-1) were analysed in the synaptic vesicle cycle. Second, a new optogenetic tool, the pOpsicle assay was described, which enables the direct visualization of synaptic vesicle (SV) release.
Activity-dependent bulk endocytosis (ADBE) enables the endocytosis of SV membrane and proteins in a fast manner during intense stimulation, resulting in bulk endosomes (also so-called large vesicles, LVs). Recycling proteins can be characterized by its site of action, whether they act at the plasma membrane (participating at the LV formation), or at the LV membrane (participating at the SV formation). ERP-1 (the C. elegans ortholog of Endophilin B) was recently identified as a possible SV recycling factor, its contribution to synaptic transmission has not been analysed before. During this project the function and possible cooperation of three proteins, ERP-1, UNC-57 (the C. elegans ortholog of Endophilin A) and CHC-1 (the C. elegans ortholog clathrin heavy chain) were studied, with a special emphasis of the site of action. It has been confirmed that these proteins participate together in synaptic vesicle recycling. Endophilins (ERP-1 and UNC-57) act both at the PM and the LV level, but while UNC-57 has been identified as the main player, ERP-1 rather has a minor role and acts as a back-up protein. CHC-1 functions the LV level in the first place, but it can compensate for the loss of UNC-57 and acts as a back-up protein at the PM.
RIM-binding protein is an evolutionarily conserved active zone protein, which interacts directly with RIM and N, P/Q, as well as L-type Ca2+ channels. RIM-BP and RIM have redundant functions in different model organisms including C. elegans, however, while the loss of UNC-10 (the C. elegans ortholog of RIM) led to drastic behavioural defects, the loss of RIMB-1 (the C. elegans ortholog of RIM-BP) led only to mild phenotypes. During this work the synaptic function of RIMB-1 and its interaction with UNC-10 and UNC-2 (C. elegans ortholog of the CaV2 1 subunit) were extensively investigated. It has been shown that RIMB-1 contributes to the precise localization of VGCCs in cooperation with UNC-10. Furthermore, it has been demonstrated, that RIMB-1 plays different roles in cholinergic and GABAergic neurons, thus it contributes to maintain a proper excitation/inhibition balance.
There are numerous available assays, which enable the indirect analysis of synaptic transmission, however, a tool, that enables the direct visualization of SV release, is highly desired. pOpsicle is a method which combines the optogenetic stimulation of cholinergic neurons with real-time visualization of SV release. A pH-sensitive fluorescence protein, pHuji, was inserted into the second intravesicular loop of the synaptic vesicle membrane protein, synaptogyrin (SNG-1). The fluorescence of pHuji is quenched inside the vesicles, but once they are released, the pH increases and pHuji can be detected. pOpsicle enables not only the direct visualization of SV exo-, and endocytosis events, but also the identification of putative SV recycling proteins.
Die Zahl der gramnegativen Bakterien auf der WHO-Liste der Antibiotikaresistenzen hat in den letzten Jahrzehnten erheblich zugenommen. Schätzungen zufolge wird die Antibiotikaresistenz bis 2050 tödlicher sein als Krebs. Die äußere Membran gramnegativer Bakterien ist aufgrund ihres wichtigsten Strukturbestandteils, des Lipopolysaccharids (LPS), sehr anpassungsfähig an Umweltveränderungen. Das LPS macht gramnegative Bakterien von Natur aus resistent gegen viele Antibiotika und führt somit zu Antibiotikaresistenz. Der bakterielle ATP-bindende Kassettentransporter (ABC-Transporter) MsbA spielt eine entscheidende Rolle bei der Regulierung der bakteriellen Außenmembran, indem er das Kern-LPS durch ATP-Hydrolyse über die Innenmembran von gramnegativen Bakterien flockt. Darüber hinaus fungiert diese Floppase als Efflux-Pumpe, indem sie Medikamente durch die innere Membran transportiert, was sie zu einem interessanten Ziel für Medikamente macht. Vor kurzem wurden zwei verschiedene Klassen von MsbA-Inhibitoren entdeckt: (1) Tetrahydrobenzothiophene (TBT), die den LPS-Transport aufheben, und (2) Chinolinderivate, die sowohl die ATP-Hydrolyse als auch die LPS-Translokation blockieren. Darüber hinaus hat die Bestimmung der 3D-Struktur von MsbA durch Rontgen- und Kryo-EM mehrere interessante Zustände der Floppase ergeben. Die Kernspinresonanzspektroskopie ist eine hervorragende biophysikalische Methode zur Ergänzung der vorhandenen 3D-Strukturdaten. Insbesondere ermöglicht die Festkörper-NMR die Untersuchung von Membranproteinen in einer nativen Umgebung (z. B. in einer Lipiddoppelschicht). In der Vergangenheit hat unser Labor mithilfe der Festkörper-NMR einige detaillierte Mechanismen von MsbA aufgedeckt. Trotz der zahlreichen Fortschritte bei der Untersuchung der ABC-Transporterprotein-Superfamilie ist der spezifische Prozess der Substrattranslokation von MsbA noch immer unbekannt. Es wird angenommen, dass dieser Translokationsprozess über die Kopplungshelices (CHs) erfolgt, die sich zwischen der Transmembranregion (TMD) und der Nukleotidbindungsdomäne (NBD) befinden. Nukleotid-Bindungsdomäne (NBD). Zu diesem Zweck wird dem Zusammenspiel zwischen der TMD und der NBD über die CHs besondere Aufmerksamkeit gewidmet, mit dem Ziel, den Prozess der Substrattranslokation mithilfe von funktionellen Assays und Festkörper-NMR zu verstehen. Bei letzterem wurden spezifische Reporter in die CHs eingeführt, um Konformationsänderungen in 2D-spektroskopischen Daten zu verfolgen. Darüber hinaus wurde zeitaufgelöste NMR eingesetzt, um die Auswirkungen verschiedener Substrate in der TMD während der ATP-Hydrolyse in der NBD sichtbar zu machen. Die einzigartigen Reporter in den CHs haben Konformationsänderungen in bestimmten katalytischen Zuständen gezeigt. Darüber hinaus scheinen verschiedene Substrate die Kinetik der ATP-Hydrolyse zu beeinflussen. Die Ergebnisse zeigten, dass einige Substrate einen bevorzugten katalytischen Zustand innerhalb des ATP-Hydrolyse Zyklus aufweisen, der möglicherweise einen gekoppelten oder ungekoppelten Kinasemechanismus hat. Diese Ergebnisse könnten verschiedene Einblicke in die molekulare Struktur potenzieller neuer Antibiotika liefern.
The phospholipid bilayers are the primary constituents of the membrane in living cells in which lipids are hold together in bilayer leaflets through a combination of different forces into the liquid crystalline (Lα) phase. Despite their thin fragile formations, the phospholipid bilayers are responsible for performing a variety of important tasks in the cells, some of which are carried out directly by the lipid bilayers and some by various integral proteins embedded within the bilayers. There have been continues efforts over the past decades to replicate the compound biophysical properties of living cell membranes in model lipid bilayers.
An important question remains unanswered: is it possible to replicate physical properties under “non-equilibrium” conditions as found in cell membranes in model lipid bilayers? In almost all previous studies, the model lipid bilayers were under static conditions – for instance, at zero lateral pressure. However, in living organisms, the cell membranes are involved in continuous (nonequilibrium) exchange and (or) transport of lipid species with the surrounding environment which consequently leads them to experience continuous lateral pressure variations. One suitable in vitro approach is to spatiotemporally control the model lipid bilayers over a time period during which they can be spatially stimulated at a level compatible to that found under in vivo conditions. This can be achieved with high spatiotemporal resolution by making lipids light-dependent through implementation of azobenzene photoswitch in their structures.
In this study, a specific azobenzene containing photolipid (AzoPC) is integrated into POPE:POPG bilayers (POPE: 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine, POPG: 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-(1'-rac-glycerol)) at ~14 mol% to construct a photo responsive model bilayers entitled as photoliposomes. Magic angle spinning solid-state NMR spectroscopy (MAS-NMR) at high field (850 MHz) is the measurement technique of choice by which it is possible to pursue the dynamics (fluidity) of the bulk lipids within the photoliposomes at atomistic resolution. It is shown that the AzoPCs undergo an efficient trans-to-cis isomerization (~85%) within the photoliposomes as the result of UV light absorption, and thermally relax back to the trans state during a period of ~65 h under the MAS measurement conditions. The order parameter measurements based on the C−H dipolar couplings reveal that the non-equilibrium cis-to-trans thermal isomerization impact of AzoPC on the fluidity of the bulk lipid is highly localized – the fluidity perturbations originate from specific order parameter changes in the middle section of the bulk lipid acyl chains. Further 1H NOESY measurements confirm the hypothesis that the azoswitch topologies in either cis and trans conformer of the photolipid is the key parameter in localized alteration of the C−H order parameters along the bulk lipid acyl chains.
Diacylglycerol kinase (DgkA) from E. coli is an enzyme responsible for the phosphorylation of diacylglycerol to phosphatidic acid, at the expense of adenosine triphosphate. Structurally, DgkA is a homo oligomer composed of three symmetric 14 kDa protomers, each of which has three transmembrane helices and one surface helix. Upon embedding within the photoliposomes, it is shown that DgkA enhances the AzoPC localization impact on the fluidity of the bulk lipids. In this regard, the results of a series of statistical simulations of lipid lateral diffusions along the bilayer leaflets in presence and absence of embedded proteins are accompanied with those of experimentally measured based upon which it is justified that membrane proteins markedly limit lipid lateral diffusions in the bilayers. In case of the DgkA proteo-liposomes with lipid-to-protein ratio of 50, it is estimated that the diffusion coefficient of lipids is above 2-fold lower compared to that of the protein free liposomes.
The cis-to-trans AzoPC isomerization and its following consequence in localized alteration of the bulk lipid fluidity is further investigated on the structural dynamics and enzymatic functionality of the embedded DgkA within the proteo-photoliposomes. It is revealed that DgkA structural dynamics are perturbated in a multi-scale, complex manner. The dynamics of residues located in different regions of DgkA changes with the light-induced AzoPC isomerization, but their time courses differ from residue to residue. For example, 29Ala, a residue on the hinge between the surface helix and membrane helix-1, exhibits the steepest time-dependent cross peak intensity changes in time-resolved NCA spectra. The impact of the lasting membrane fluidity perturbation on the enzymatic functionality of the embedded DgkA is subsequently measured which demonstrates a significant variation under cis- and trans-AzoPC conformations within the proteo-photoliposomes.
Probing the photointermediates of light-driven sodium ion pump KR2 by DNP-enhanced solid-state NMR
(2021)
KR2 is a light-driven sodium ion pump found in marine flavobacterium Krokinobacter Eikastus. The protein belongs to the microbial rhodopsin family, which is characterized by seven transmembrane helices and a retinal cofactor covalently bound to a conserved lysine residue through a Schiff base linkage. Specific features of KR2 and other sodium pumping rhodopsins are the NDQ motif, the N-terminal helix capping the protein at the extracellular side, and the sodium ion bound at the protomer interface in the pentameric structure. The ability to pump sodium ions was a surprising discovery since the positive charge at the Schiff base was long thought to hinder the transport of non-proton cations and the Grotthuss mechanism could not be applied to explain the Na+ transport. The photocycle of KR2 revealed by flashed photolysis and ultrafast femtosecond absorption spectroscopy consists of consecutive intermediates, named K, L, M, and O.
Here, DNP-enhanced ssNMR was used to analyze various aspects of these intermediate states. The K/L-state can be generated and trapped by in-situ illumination inside the magnet at 110 K. The trapping of L-state together with the K-state at this temperature is unexpected as this usually leads to the trapping of only K-state in bacteriorhodopsin (BR), proteorhodopsin (PR), and channelrhodopsin 2 (ChR2). This observation suggests a lower energy barrier between K- and L-state in KR2. For the O-state, the intermediate was generated by illuminating outside the magnet, followed by rapid freezing in liquid nitrogen and transfer to the magnet. Based on these procedures, the retinal conformation, and the electrostatic environment at the Schiff base in KR2 dark, K-, L- and O-intermediates were probed using 13C-labeled retinals bound to 15N-labeled KR2 by both 1D and 2D magic angle spinning (MAS) NMR experiments.
The obtained data show an all-trans retinal conformation with the distortion of 150° at H-C14-C15-H in the dark state whereas the retinal has a 13-cis, 15-anti conformation in the K- and L-state after light activation. Differences between K- and L-intermediates were observed. The retinal chemical shifts of the K-state show a large deviation from the model compound behavior between the middle and end part of the polyene chain. In the L-state, these differences are much less pronounced. These observations indicate that the light energy stored in the K-state dissipates into the protein in the subsequent photointermediate states. Furthermore, an additional shielding observed for C14 in L-state indicates the slight rotation toward a more compact 13-cis, 15-syn conformation. The distortion of the H-C14-C15-H angle in the L-state (136°) is larger than in the dark state. This twist of the retinal in the L-state would play an important role in lowering the pKa of the Schiff base, which is a prerequisite for the proton transfer from the Schiff base to the proton acceptor (D116). The electrostatic environments at the Schiff base in K- and L-states cause a de-shielding of the 15N nitrogen compared to the dark state. This indicates a stepwise stronger interaction with the counterion as the Schiff base proton moves away from the Schiff base and comes closer to the D116 in the transition from K- to L-state and approaches the proton transfer step during the M-state formation. In the O-state, the retinal was found to be in the all-trans conformation but differed to the dark state in the C13, C20, and Schiff base nitrogen chemical shifts. The largest effect (9 ppm) was observed for the Schiff base nitrogen, which could be explained by the effect of the positive charge of bound Na+ near the Schiff base in the O-state, coordinated by N112 and D116 as observed in the O-state crystal structure in the pentameric form.
The structural change at the opsin followed the retinal isomerization and the energy transfer from the chromophore to the surrounding were also investigated in this thesis using various amino acids labeling schemes. Moreover, 1H-13C hNOE in combination with CE-DNP was applied to probe the dynamics of retinylidene methyl groups and 23Na MAS NMR was employed to detect the bound sodium ion at the protomer interface in KR2 dark state.
Resistant microbes are a growing concern. It was estimated that about 33,000 of people die because of the infections caused by multidrug resistant bacteria each year in Europe (ECDC, 2018, https://www.ecdc.europa.eu/). Bacteria can acquire resistance against toxic compounds via different mechanisms and intrinsic active efflux is one of the first mechanisms deployed by bacterial cells. The membrane-localized efflux pumps catalysing this reaction, extract toxic compounds from the interior of the cell and transport these to the outside, thereby maintaining sub-lethal toxin levels in the cytoplasm, periplasm and membranes. Gram-negative three-component efflux pumps, analysed in this study, are composed of an inner membrane protein, a member of the Resistance-Nodulation cell Division (RND) superfamily, an Outer Membrane Factor (OMF) protein and a Membrane Fusion Protein (MFP) that connects the two afore mentioned components into an active efflux pump. The pumps described in this work, AcrAB-TolC and EmrAB-TolC, are drug efflux pumps belonging to the RND and MFS superfamilies, respectively, while CusCBA is an efflux pump that belongs to the RND heavy metal efflux family. Another efflux pump that was used as a model for the design of an in vitro assay for the silver ion transport studies, CopA, belongs to the P-type ATPase superfamily. All pumps analysed in this study are part of the resistance system of Escherichia coli, which is a highly clinically relevant pathogen.
In order to examine the AcrAB-TolC, CopA and CusA efflux pumps, the individual components were separately produced in E. coli, purified to monodispersity and reconstituted in large unilamellar vesicles, LUVs. Means for the optimized production and adequate conditions for efficient reconstitution were presented in this study. The activity of AcrB in LUVs was detected using fluorescence quenching of the dye 8-hydroxy-1,3,6 pyrenetrisulfonate (pyranine), which is incorporated inside the proteoliposomes and is sensitive to the pH changes in its surrounding. The inactive AcrB variant with a substitution in the proton relay network, D407N, showed no activity in proteoliposomes, which correlates with the measurements done in empty liposomes. When AcrA was co-reconstituted with AcrB D407N proteoliposomes it did not restore protein activity. To test the assembly of the AcrAB-TolC pump out of its single components, an in vitro assay was established where the complex assembly was tested with AcrAB- and TolC-containing liposomes. These experiments showed putative AcrAB-TolC formation in the presence or absence of a pump substrate, taurocholate, as well as in the presence of the pump inhibitor, MBX3132. The assembly appeared stable over time and results were invariant in the presence or absence of a pH gradient across the AcrAB-containing membrane.
After determination of the ATPase activity of the P-type ATPase, CopA, in detergent micelles, the protein was reconstituted in LUVs. Quenching of the Ag+-sensitive dye Phen Green SK (PGSK), present on the inside of the CopA-containing proteoliposomes, was observed in presence of ATP and Ag+. Under the same conditions, but in absence of Ag+-ions, quenching was reduced by 80 % after 300 seconds. No PGSK-quenching was observed in control liposomes in the presence of ATP and Ag+. The additional presence of sodium azide led to minimal reduction of the PGSK-quenching as expected since sodium azide is not an inhibitor of P-type ATPases, but the quenching rate was similar to that of the same experimental condition with control liposomes.
The RND superfamily member CusA, as part of the tripartite CusCBA efflux pump, has been proposed to sequester Ag+ or Cu+ from either the cytoplasmic or periplasmic side of the inner membrane. The periplasmic transport of silver ions was implied from an in vitro assay where the quenching of a pH sensitive dye, 9-amino-6-chloro-2-methoxyacridine (ACMA), indicates acidification of the lumen of the proteoliposomes containing CusA when an inwardly directed pH was imposed. The same experiment with the CusA D405N variant, which was previously reported to be an inactive variant, also led to ACMA quenching, although at a slightly lower rate. Under application of an inwardly directed pH and a (negative inside), CusA-containing proteoliposomes showed a strong quenching of the incorporated PGSK dye, suggesting strong Ag+ influx.
The Major Facilitator Superfamily-(MFS-) type EmrAB-TolC pump has an analogous structural setup as the RND-type AcrAB-TolC pump. To examine the efflux of one of its substrates, carbonyl - cyanide m-chlorophenylhydrazone (CCCP), a plate-based susceptibility assay was used. The presence of the EmrAB-TolC pump confers lower susceptibility levels towards CCCP in E. coli, compared to cells not expressing the pump or cells expressing only the MFS component, indicating that EmrAB-TolC extrudes CCCP.
The work done in this study opens up a path towards investigation of drug and metal resistance in vitro. The methodologies to obtain proteoliposomal samples of multicomponent efflux pumps and subsequent measurements of drug/metal ion and H+ fluxes, as well as the determination of pump assembly are crucial for the future research on pump catalysis and transport kinetics. The in vivo drug-plate assays done in this work provide initial insights for future investigations of the drug susceptibility of E. coli expressing the MFS-type tripartite efflux pumps.
Cytochrome c oxidases are among the most important and fundamental enzymes of life. Integrated into membranes they use four electrons from cytochrome c molecules to reduce molecular oxygen (dioxygen) to water. Their catalytic cycle has been considered to start with the oxidized form. Subsequent electron transfers lead to the E-state, the R-state (which binds oxygen), the P-state (with an already split dioxygen bond), the F-state and the O-state again. Here, we determined structures of up to 1.9 Å resolution of these intermediates by single particle cryo-EM. Our results suggest that in the O-state the active site contains a peroxide dianion and in the P-state possibly an intact dioxygen molecule, the F-state may contain a superoxide anion.
Investigation of co-translational protein folding using cryo-EM and solid-state NMR enhanced by DNP
(2020)
Die zelluläre Proteinbiosynthese findet am Peptidyltransferase-Zentrum innerhalb der großen ribosomalen Untereinheit statt. Die neu synthetisierte Polypeptidkette passiert den ribosomalen Exit-Tunnel, der 80-100 Å lang und 10-20 Å breit ist. Proteinfaltung findet kotranslational statt, während die Peptidkette durch den ribosomalen Tunnel geschleust wird. Zu welchem Ausmaß die Proteine ihre native Struktur noch am Ribosom gebunden annehmen, steht im Fokus aktueller Studien. Verschiedene Methoden, die naszierende Proteinkette am Ribosom zu arretieren und die Faltung des Proteins untersuchen zu können, wurden entwickelt. Zur Herstellung von Ribosom naszierenden Proteinkomplexen (RNCs) in vivo werden Arrestierungspeptide (APs) verwendet. Ein oft genutztes AP ist die 17 Aminosäuren lange SecM Sequenz des E. coli Sekretionsmonitors, das C-Terminal an das zu untersuchende Protein kloniert werden kann und dadurch die Peptidkette am Ribosom behält. RNCs wurden mittels verschiedener Methoden untersucht, einschließlich Proteolyse-Experimenten, enzymatischen Aktivitätsmessungen, FRET, Cryo-EM und NMR-Spektroskopie. Alle Methoden zeigten auf, dass sich die Proteine kotranslational falten und auch am Ribosom eine funktionale Struktur annehmen können. Außerdem konnte eine Peptidkette eine α-Helix innerhalb des Ribosoms ausbilden. Ebenso wurden nicht-native kompakte Strukturen innerhalb der Vestibule detektiert.
Die Translation ist ein nicht-uniformer Prozess und der genetische Code degeneriert mit bis zu sechs Codons, die eine einzelne Aminosäure kodieren. Die Verteilung dieser synonymen Codons ist nicht zufällig und sie werden mit verschiedenen Frequenzen innerhalb eines ORFs verwendet. Codons mit einer höheren tRNA Häufigkeit werden schneller eingebaut als Codons, die seltener verwendet werden. Diese seltenen Codons sind häufig zwischen Proteindomänen oder Sekundärstrukturelementen platziert und könnten daher zur Separierung von Faltungsevents dienen. Dass der Austausch von synonymen Codons nicht ohne Folgen ist, zeigten verschiedene Studien. Buhr et al. (2016) zeigte, dass der synonyme Austausch die Translationsgeschwindigkeit, aber auch die Proteinkonformation des bovinen Augenlinsenproteins γB crystallin (GBC) beeinflusst. Während die unmodifizierte Gensequenz aus B. taurus in E. coli langsamer translatiert wurde und zu einem vollständig reduzierten GBC Protein (U) führte, wurde die harmonisierte Genvariante, die der Codon-Verwendung in E. coli angepasst war, schneller exprimiert und resultierte in einem teilweise oxidierten GBC Protein (H). Dieser Befund war der Ausgangspunkt für diese Doktorarbeit.
Die gemessenen Oxidationsunterschiede basieren auf der unterschiedlichen Translationsgeschwindigkeit der beiden Gensequenzen. Die N-terminale Domäne (NTD) des Zweidomänen-Proteins GBC enthält sechs der insgesamt sieben Cysteinreste. Nur in dieser Domäne wurde Oxidation detektiert und die drei Cysteine Cys18, Cys22 und Cys78 bilden eine Ansammlung mit einem Abstand von 5.4-6.4 Å. Um zu untersuchen, ob die Unterschiede bereits nach der Translation der NTD ausgebildet werden, wurde ein Ein-Domänen-Konstrukt hergestellt. Dieses Konstrukt beinhaltete die Aminosäuren 1-82, aber nicht den Peptidlinker, der beide Domänen verbindet. Allerdings wurden bei der Translation der ersten 70 Aminosäuren die meisten Translationspausen detektiert. Das 2D 1H-15N HSQC wies anhand der unterschiedlichen chemischen Verschiebung der Signale auf eine gefaltete Proteinstruktur hin. Daher konnte sich die NTD ohne Beteiligung der CTD eigenständig falten. Zugabe von DTT zu beiden Proteinvarianten U und H führte zu keinem messbaren Effekt. Im Gegensatz zu dem Volllängen-Protein, in dem die Variante H teilweise oxidiert war, war die NTD der Variante H vollständig reduziert.
Zusätzlich sollte geklärt werden, ob auch mögliche Disulfidbrücken im Inneren des Ribosoms ausgebildet werden können. Dann könnte in beiden Genvarianten eine anfängliche Disulfidbrücke ausgebildet werden und durch die unterschiedliche Translationsgeschwindigkeit die Disulfidbrücke in der langsamen Genvariante im E. coli Zytosol reduziert werden, während diese in der schneller translatierten Variante von der CTD geschützt wird. Um zu untersuchen, ob in der Tat Disulfidbrücken im ribosomalen Tunnel ausgebildet werden können, wurden GBC-Fragmente mittels der SecM Sequenz an das Ribosom arretiert und diese RNCs mittels theoretischer Simulation, Festkörper-NMR, Massenspektrometrie und Cryo-EM gemessen.
Theoretische Simulation mittels flexible-mecanno zeigten, dass der ribosomale Tunnel groß genug für die Ausbildung verschiedenster Disulfidbrücken ist. In einem U32SecM Konstrukt, das vier Cysteine und die SecM Sequenz beinhaltet, konnten alle theoretisch möglichen Disulfidbrücken gebildet werden.
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