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Synthese, Reaktivität und strukturelle Vielfalt im Festkörper von Ferrocenylboranen und -boraten
(2013)
Channelrhodopsin-2 (ChR2) is a light-gated cation selective channel from the unicellular alga Chlamydomonas reinhardtii, which is involved in phototaxis and photophobic responses. As other rhodopsins, ChR2 comprises a seven-transmembrane helix (TMH) motif and a retinal as the light-sensitive chromophore. The chromophore is covalently attached via a protonated Schiff base to the conserved lysine residue Lys257 located in TMH7. Based on its primary sequence and the all-trans configuration of the retinal in the ground state, ChR2 is assigned to the type I rhodopsins, also referred to as microbial-type rhodopsins. Upon light activation, the retinal isomerizes from the all-trans to the 13-cis form. This photoisomerization, which is accompanied by conformational changes of the protein, eventually leads to the opening of the channel and cation translocation. Cation flux during the conductive state leads to depolarization of the cell membrane and subsequent triggering of action potentials when expressed in neurons. Therefore, ChR2 has become the most versatile optogenetic tool, enabling a non-invasive investigation of neural circuits at high spatial and temporal resolution. With the rapidly increasing importance of ChR2 as a tool in neurobiology and cell biology, structural information is the prerequisite to an unambiguous understanding of the molecular mechanisms of this unique light-activated ion channel. The coupling between isomerization and structural alterations is well understood for other microbial-type rhodopsins, like bacteriorhodopsin (bR), halorhodopsin (HR) and sensory rhodopsin II (SRII). In case of ChR2, the first data on light-induced conformational changes came from spectroscopic studies and structural information is still missing. However, in order to fully understand the mechanism of light transduction by ChR2, it is necessary to determine the changes in the protein structure at specific steps in the photocycle.
By the time I started my PhD thesis, there was no structural information of ChR2 available. Therefore, the objective of this thesis was to obtain structural information of the transmembrane domain containing the first 315 amino acids of ChR2 by cryo electron crystallography. Besides revealing the structure of membrane proteins, cryo-EM of two-dimensional (2D) crystals is ideal for investigating conformational changes in membrane proteins induced by different stimuli. Therefore, the second objective of my thesis was the investigation of light-induced conformational changes in the slow C128T ChR2 mutant. The ~1,000 times longer lifetime of the open state of the C128T mutant compared to the wild-type allowed to trap different intermediates that accumulate during the photocycle.
In 2012, the X-ray structure of a channelrhodopsin-1/channelrhodopsin-2 chimaera (C1C2) at 2.3 Å resolution in the closed dark-adapted state was published (Kato et al., 2012). The structure revealed the essential molecular architecture of C1C2, including the retinal-binding pocket and the putative cation conduction pathway. Together with biochemical, spectroscopic, mutagenesis experiments, and the high-resolution model, some functionally important residues of ChR2 have been identified. However, unambiguous explanation of the molecular determinants that contribute to activation (gating) and transport were still mostly unknown.
RESULTS AND CONCLUSIONS
The first half of my theses dealt with 2D crystallization of ChR2. I succeeded in obtaining 2D crystals of ChR2 of four different types, which differed in size, crystal packing, crystal contacts and resolution, yielding structure factors up to 6 Å resolution. The crystals were grown by reconstituting the protein with different lipids at various lipid-to-protein ratios. The best crystals formed with the synthetic lipid DMPC and EPL upon detergent removal by dialysis. The projection maps calculated from these crystals revealed the overall structure of C128T ChR2 at 6 Å resolution and were published in 2011 (Müller et al., 2011). Surprisingly, ChR2 was found to be a dimer in all crystal types. The ChR2 dimer was stable both in detergent solution and in the presence of lipids for 2D crystallization. The monomers clearly showed the expected densities for the seven TMHs.
The arrangement of the ChR2 dimers on the four 2D lattices was different. However, comparison of the individual rojection maps revealed no significant differences within the ChR2 interface in the four crystal forms. The observation that the structure of the dimer was the same in all four crystal forms and in different lipids suggested strong specific contacts between the two protomers and implied that the protein was also dimeric in the native membrane. These findings were in agreement with Western blot analysis of plasma membranes from oocytes expressing ChR2 and laser-induced liquid bead ion desorption mass spectrometry, which both showed ChR2 as a dimer. The unusual stability of the ChR2 dimer contrasts with other microbial rhodopsins, which exist in different oligomeric states, i.e. monomers, trimers or dimers. These observations raised the question whether the functional unit is the monomer or the dimer.
The comparison of the projection map of the light-driven proton pump bR at the same resolution showed similar overall dimensions. Based on this comparison, the densities which became evident in the ChR2 projection maps could be assigned to the corresponding seven densities in bR. The shape of the densities near the dimer interface suggested that TMHs 2, 3, and 4 are oriented more or less perpendicular to the membrane plane, while the other four helices appear to be more tilted, as in bR.
Based on the high-resolution bR structure and the projection structures obtained, I have built a homology model. On the basis of this homology model, several residues found in the dimer interface were selected for mutational studies in order to disrupt the dimer interface.
The investigation of light-induced conformational changes in C128T ChR2 was the second part of my thesis. I designed an experimental setup for trapping light-induced conformational changes in C128T ChR2. In addition, I optimized the sample preparation in a way that the different illumination conditions did not alter the quality of the crystals. I have trapped two different functional states, namely the conductive open state and the non-conductive closed dark-adapted state.
In order to visualize the location and the extent of conformational changes, projection difference maps were calculated between the open and the closed state. Visual inspection of the difference maps between the open and the two closed states revealed three difference peaks that map to the TMHs 2, 6, and 7, indicating significant and specific rearrangements of these helices. The strong pair of positive/negative peaks at TMH6 suggests an outward tilt movement of approximately 2 Å. Close comparison of similar work on bR revealed that this movement is likely to occur at the cytoplasmic end of TMH6. A second highly significant negative peak is observed at TMH7, indicating a less pronounced tilt compared to TMH6. The third negative peak at TMH2 indicates a loss of density in this region. No significant differences were recorded at the TMH1, 5 and at the dimer interface formed by TMH3 and 4.
I succeeded in trapping and characterizing the open and closed state in the photocycle of ChR2 and could demonstrate that the transition from the closed to the open state is linked to significant light-induced tilt movements of TMH6 and 7, plus a loss of order in TMH2. These conformational changes are likely to create a large water-filled conducting pore, which seems to be required for the conductance of up to 2,000 ions per photocycle. The previously mentioned spectroscopic studies support the difference structures I obtained. This approach sets the stage for studying structural changes accompanying the formation and decay of other photocycle intermediates in ChR2. Future studies will aim at three-dimensional maps of the open and closed state at higher resolution.
Structural determinants for substrate specificity of the promiscuous multidrug efflux pump AcrB
(2013)
Opportunistic Gram-negative pathogens such as Escherichia coli, Klebsiella pneumoniae, Acinetobacter Baumanii and Pseudomonas aeruginosa are becoming more and more multiresistant against many commonly available antibiotics [39, 40]. An important resistance mechanism of Gram-negative bacteria is the efflux of noxious compounds by tripartite systems [39, 41-44]. The best studied and most clinically relevant tripartite system is the AcrA-AcrB-TolC system of Escherichia coli, where substrate recognition and energy transduction takes place in the inner membrane protein AcrB. AcrB has a remarkably huge substrate spectrum and can recognize structurally diverse molecules, such as hexan in contrast to erythromycin, as its substrates [45]. Therefore, overproduction of the tripartite system can render a Gram-negative pathogen resistant against multiple antibiotics at once. The mechanisms of how AcrB is able to recognize such an enormous spectrum of molecules as substrates, without compromising its specificity (e.g. by neglecting essential compounds like lipids or gluclose as its susbtates), remained puzzling. Structural insight into substrate specificity was so far limited to two co-crystal structures of AcrB, where minocycline and doxorubicin, respectively, were identified bound to an internal binding pocket of AcrB. This binding pocket is particularly deeply buried into internal parts of the T monomer of AcrB and was, therefore, denoted deep binding pocket (DBP). Analysis of several AcrB co-crystal structures with substrate molecules bound to the DBP [4, 23, 25] indicated that the substrate promiscuity involved multisite binding modes within the DBP. Multisite binding modes, where different substrate molecules can bind to slightly different positions and orientations to the same binding pocket, is a common feature of multidrug recognizing proteins such as QacR or BmrR [27-29]. Nevertheless, AcrB's substrate spectrum is much broader than substrate spectra of most other multidrug recognizing proteins. Therefore, it is likely that additional mechanisms are involved in mediating the observed high substrate promiscuity of AcrB. In our recently published high-resolution AcrB/doxorubicin co-crystal structure (pdb entry: 4DX7 [23]) we were able to identify two additional substrate binding pockets in the L monomer of AcrB: i) the access pocket (AP), with an opening towards the periplasm, and ii) a putative binding site in a groove between transmembrane helices 8 and 9 (TM8/TM9 groove), accessible from the lipid layer of the inner membrane. Both binding pockets are likely to be access sites for substrates towards AcrB. Furthermore, each of the binding pockets are possibly specialized to recognize a specific subset of the entire substrate spectrum of AcrB, i.e. highly hydrophobic substrates (e.g. n-dodecyl-ß-d-maltoside or sodium dodecylsulfate) might access AcrB towards the TM8/TM9 groove and water soluble substrates (e.g. berberine) might access AcrB towards the AP. Since substrates will accumulate in the membrane or the periplasm according to their hydrophilic or hydrophobic nature, substrates will be "pre-selected" by the medium, rather than by the protein itself, and guided to their appropriate access site. This process is proposed to be called "medium- mediated pre-selection". The AcrB/doxorubicin co-crystal structure (pdb entry: 4DX7 [23]) furthermore revealed that the AP and DBP are in next neighborhood to each other and are separated by a switch loop. This switch loop adopts distinct conformations in the L, T and O monomers. Specific switch loop conformations are strongly involved in coordinating the selective occupation of both binding pockets, the AP and the DBP. The conformation of the switch loop in the L monomer (L-switch loop) opens the AP and closes the DBP, whereas the conformation of the switch loop in the T monomer (T-switch Loop) opens the DBP and closes the AP. An analysis of all asymmetric AcrB structures indicated that the L-switch loop is able to adopt multiple distinct conformations, whereas the conformation of T-switch loop remained largely congruent in all crystal structures. Moreover, each distinct switch loop conformation, observed in co-crystal structures of AcrB with occupied AP [4, 23], was perfectly adapted to the bound substrate molecule. Therefore, the putatively flexible switch loop is likely to act as an adaptive module and mediates a high binding pocket plasticity without altering the global protein structure. This binding mode is called adaptor-mediated binding mechanism, where an flexible adaptive module (like the switch loop) is able to adapt the surface shape of an binding pocket to different substrate molecules. Furthermore, structural and biochemical analyses of an AcrB G616N variant, revealed the involvement of specific switch loop conformations in the substrate specificity of AcrB. A substitution of G616, located on the switch loop, to N616 was able to alter the conformation of the switch loop exclusively in the L monomers of AcrB, whereas the switch loop conformations in T and O monomers remained congruent to the conformations observed in crystal structures of wildtype AcrB. Moreover, cells producing the AcrB G616N and MexB, both bearing the G616N amino acid substitution, exhibited a reduced resistance against certain substrates, whereas the resistance against most other substrates remained on the level of wildtype AcrB. Correlations of the phenotypes with minimal projection areas, a novel 2-spatiodimensional parameter which approximates the size of a substrate molecule, revealed that AcrB variants with a G616N substitution have a reduced efflux activity for exclusively large substrate molecules. The rejection of large substrates is most likely connected with altered L-switch loop conformations....
C-Typ Lektin-ähnliche Rezeptoren (CTLRs) auf Lymphozyten des Immunsystems modulieren deren Effektorfunktionen wie Zytotoxizität oder Zytokinsekretion. Die Gene dieser Immunrezeptoren befinden sich in einer definierten genomischen Region, dem Natürlichen Killer Genkomplex (NKC), welcher im Menschen auf Chromosom 12 und in der Maus auf Chromosom 6 lokalisiert ist. Namensgebend für diesen Gencluster ist die erste Beschreibung von CTLRs auf Natürlichen Killerzellen (NK-Zellen), den Effektorlymphozyten des angeborenen Immunsystems. Einige NKC-kodierte CTLR, insbesondere Vertreter der C-Typ Lektin Familie 2 (CLEC2)-Rezeptorfamilie, werden jedoch auch in nicht-lymphozytären Zellen (z.B. humanes KACL in Keratinozyten, Maus Clr-f in Darmepithelzellen) vorgefunden und in Zusammenhang mit einer gewebsspezifischen Immunüberwachung gebracht. Bemerkenswerterweise sind die Lymphozytenassoziierten Rezeptoren dieser CLEC2-Proteine ebenso CTLRs, welche zudem eng benachbart zu den CLEC2-Proteinen im NKC kodiert sind, sodass es sich um genetisch gekoppelte Rezeptor-Liganden-Paare mit immunologischer Funktion handelt.
Zu Beginn der vorliegenden Arbeit richtete sich das Interesse auf ein bislang uncharakterisiertes Mitglied der CLEC2-Proteinfamilie (CLEC2L), das jedoch außerhalb des NKC und in unmittelbarer Nachbarschaft zu einem weiteren und ebenso uncharakterisierten CTLR (KLRG2) kodiert ist. Im Unterschied zu anderen Mitgliedern der CLEC2-Familie ist CLEC2L (wie auch KLRG2) in Säugetieren hochkonserviert. Im Rahmen dieser Arbeit wurde der Frage nachgegangen, ob CLEC2L wie andere Mitglieder der CLEC2-Proteinfamilie eine gewebsspezifische Expression aufweist, mit einem genetisch gekoppelten CTLR, d. h. mit KLRG2, interagiert und funktionell in Verbindung mit dem Immunsystem gebracht werden kann. Ziel dieser Arbeit war es somit, eine detaillierte Expressions- und Funktionsstudie zu CLEC2L durchzuführen.
Mittels quantitativer Echtzeit-PCR und in situ Hybridisierung konnte CLEC2L-RNA im humanen und Maus-Gehirn nachgewiesen werden. Da die Mengen dort das Expressionsniveau in anderen Organen bei Weitem überstiegen, wurde das CLEC2L-kodierte Protein als BACL (engl. Brain-Associated C-type Lectin) neu benannt. Ektop exprimiertes BACL bildet ähnlich wie viele andere CLEC2-Mitglieder ein disulfid-verknüpftes Homodimer auf der Zellmembran von Säugetierzellen. Um die endogene Proteinexpression dieses gehirnassoziierten „Waisen"-Rezeptors zu charakterisieren, wurde die BACL-Ektodomäne rekombinant produziert und als Immunogen zur Herstellung BACLspezifischer Antikörper eingesetzt. Mit diesen Antikörpern und einer Kombination immunologischer Techniken wie Immunhistochemie, Immunfluoreszenz und Immunpräzipitation konnte die Präsenz von BACL auf humanen und Maus-Neuronen des Gehirns mit einer besonders ausgeprägten Expression in Purkinje-Zellen zum ersten Mal gezeigt werden. Neben dem Gehirn wurden andere Bereiche des Nervensystems, darunter Spinalganglien und Retina, auf die Expression des BACL-Proteins untersucht. Hierbei konnte mittels Immunfluoreszenz und hochauflösender konfokaler Mikroskopie gezeigt werden, dass BACL mit Neuronenmembranen assoziiert ist. Die durchflusszytometrische Analyse von in vitro kultivierten Neurosphären untermauerte die Expression von endogenem BACL als membranständiges Oberflächenprotein.
Diverse Ansätze zur Identifizierung von Interaktionspartnern von BACL erbrachten letztlich keine eindeutigen Ergebnisse. KLRG2 wurde ursprünglich aufgrund seiner benachbarten genomischen Lokalisation als möglicher Rezeptor von BACL favorisiert, jedoch konnten weder Reporterassays noch durchflusszytometriebasierte Bindungsanalysen eine Interaktion dieser beiden Proteine aufzeigen. Auch die aus den massenspektrometrischen Analysen von humanen und Maus BACL-Immunpräzipitaten erhaltenen Kandidatenproteine konnten letztendlich nicht als Interaktionspartner von BACL eindeutig verifiziert werden.
Eine mögliche immunologische Bedeutung von BACL in vivo wurde im Rahmen von Tumorimplantationsexperimenten mit BACL-exprimierenden Tumorzellen untersucht. Hierbei wurde das Tumorwachstum von BACL- mit Kontroll-Transfektanten in C57BL/6 Mäusen verglichen. Der beobachtete Effekt des verlangsamten Tumorwachstums nach BACL-Überexpression war jedoch nicht auf BACL-Erkennung durch Lymphozyten zurückzuführen, wie anhand von immundefizienten Rag1-k.o. und NOD-SCID-gammak.o. Mäusen gezeigt werden konnte.
Insgesamt liefert diese Arbeit die Erstbeschreibung des bislang uncharakterisierten CTLRs BACL. Das Protein teilt strukturelle Merkmale mit Mitgliedern der CLEC2-Familie, unterscheidet sich jedoch deutlich durch (i) seine hohe Konservierung in Säugetieren, (ii) seine Kodierung außerhalb des NKC und (iii) seine pan-neuronale Expression. Die Erkenntnis, dass BACL in Maus- und in humanen Neuronen exprimiert wird, wirft die Frage nach seiner funktionellen Relevanz auf. Als Membranprotein könnte es eine wichtige Rolle in der neuronalen Kommunikation und bei zellulären Kontakten spielen. Die Frage nach der Funktion von BACL wird in zukünftigen Forschungsarbeiten zu klären sein.
Die Idee photolabile Schutzgruppen zur temporären Inaktivierung von Biomolekülen zu verwenden, um deren Funktion dann in einem biologischen System präzise orts- und zeitaufgelöst wieder zu aktivieren und so biologische Prozesse genau steuern zu können, wurde erstmals Ende der 1970er Jahre von J. W. Engels und von J. F. Hoffman verfolgt. Seit diesen ersten Arbeiten im Bereich des „Cagings“ wurde in den vergangenen Jahrzehnten eine Vielzahl von Arbeiten auf diesem Gebiet veröffentlicht und mit nahezu alle wichtigen Klassen von Biomolekülen wurden Caging-Experimente durchgeführt. Das Caging von Nukleinsäuren ist noch ein recht neues Feld. Es gab aber aufgrund der Beteiligung von Nukleinsäuren an vielen zentralen zellulären Prozessen im letzten Jahrzehnt ein enorm gesteigertes Interesse an lichtinduzierbaren Nukleinsäuren, vornehmlich zur lichtgesteuertem Genregulation. Der Arbeitskreis von Prof. Heckel befasst sich unter anderem mit dem Caging von Nukleinsäuren, wobei die zentrale Strategie im Anbringen der photolabilen Schutzgruppen an den Nukleobasen besteht. Dies hat den Hintergrund, dass auf diese Art und Weise die Wechselwirkung mit anderen Strängen durch Störung der Watson-Crick-Basenpaarung verhindert werden kann. Die Watson-Crick-Basenpaarung ist das zentrale Element für die Funktionalität nahezu aller Nukleinsäure-vermittelter Prozesse. In den vergangenen Jahren konnte mit dieser Strategie unter anderem erfolgreich die Aktivität von siRNAs und Aptameren mit Licht kontrolliert werden. Alle vier Projekte, welche in dieser Arbeit verfolgt wurden, befassten sich mit dem Caging von Nukleinsäuren. ...
In the past century, scientists have realized that venoms are a source of a number of natural substances presenting a wide range of pharmacological properties and often displaying a high specificity for their targets. Thus, the field of toxinology came into being, which is defined as the study of toxic substances of biological origin. Toxins are found in a wide variety of animals, including fish, cone snails, scorpions, snakes, and even some mammals. To be classified as venom, these must contain substances, i.e. toxins, which disturb physiological processes and must be deliberately delivered to the target animal. Snakes have evolved one of the most sophisticated mechanisms for venom delivery. Envenomation by snakebite can induce and inhibit aggregation/agglutination of platelets as well as inhibit/activate hemostasis, but also disrupt other physiological functions via neurotoxins and angioneurin growth factors. Snake venoms contain a substantial amount of C-type lectin-related proteins (CLRPs) which are known to function, notably, as integrin inhibitors. CLRPs are heterodimers composed of homologous α and β subunits which can assemble either covalently or noncovalently to oligomers, resulting in αβ, (αβ)2 and (αβ)4 structures. Some of the main targets of CLRPs are membrane receptors, coagulation factors, and proteins essential to hemostasis. The platelet collagen receptors GPVI and α2β1 integrin as well as the von Willebrand factor receptor GPIb play important roles in platelet activation and aggregation and are considered main targets of antithrombotic drugs. In this thesis, the integrin α2β1 is particularly considered as it is the sole collagen-binding integrin on platelets. Reduced expression of this platelet receptor results in dysfunction of platelet responses. Equivalently, overexpression of α2β1 integrin results in an increased risk of thrombosis. As a result, selective inhibitors of the collagen-α2β1 interaction could give rise to effective antithrombotic drugs. Integrins are large receptors which mediate cell-cell contacts and the binding of cells to the extracellular matrix (ECM). Therefore, they play a role in physiological processes, e.g. hemostasis and immunity, as well as in pathological processes, e.g. tumor angiogenesis and atherosclerosis. 18 α and 8 β integrin subunits, with nine α subunits containing an additional A domain, associate non-covalently to form 24 heterodimers with distinct binding specificities. Integrin collagen receptors are a subclass of four receptors which all utilize the β1 subunit. The α2β1 integrin is a collagen-binding receptor expressed not only on platelets, but also on endothelial and epithelial cells. Consequently, this integrin is also essential for cell adhesion and migration playing a role in angiogenesis as well as tumor metastasis. To date, there are five known antagonists of α2β1 integrin: EMS16, rhodocetin, vixapatin, and most recently rhinocetin and flavocetin-A. The first four have been shown to be specific for the integrin α2A domain, the major collagen-binding domain. All these antagonists are CLRPs and present new leads for drug design. In the past few years, many insights into the structure and function of rhodocetin were obtained. Monoclonal antibodies proved to be advantageous in disclosing this information, making them not only useful as therapeutic agents, but also as tools for protein characterization. The venom of the Vipera palaestinae snake was recently shown to contain an α2β1 integrin inhibitor, which prevented the integrin from binding collagen. This inhibitor, called vixapatin, was the initial focus of this dissertation. Vixapatin’s interaction with the α2β1 integrin needed further characterization on a molecular and cellular level to assess its medical potential and monoclonal antibodies were to be used as a tool. Originally, vixapatin had been isolated by reversed-phase high-performance liquid chromatography. To avoid the stringency of this method, for this study, it was replaced with gentler chromatographic methods. First, the α2β1 integrin inhibitor was isolated from the crude snake venom with affinity chromatography using the α2A domain as bait, establishing a method to quickly screen venoms for α2β1-binding proteins which affect the collagenintegrin interaction. The applicability of this method to other snake venoms was shown by isolating an α2A domain-specific toxin from the venom of Trimeresurus flavoviridis. To allow further characterization of both these toxins, gel filtration and ion exchange chromatography were employed to purify the protein without the α2A domain. These classical protein purification methods resulted in similar separation patterns of both the V. palaestinae and T. flavoviridis venom proteins. Purified proteins exhibiting the potential of inhibiting integrinbinding to collagen were analyzed by two-dimensional gel electrophoresis. Both VP-i and flavocetin-A, the integrin inhibitors from V. palaestinae and T. flavoviridis, respectively, were shown to have more complex structures than was evident from the purification. Each consisted of four low-molecular-weight proteins which assembled into two bands (for VP-i) or one single band (for flavocetin-A) under non-reducing conditions. Mass spectrometry analyses revealed VP-i to belong to the family of CLRPs, just like vixapatin does. However, these two proteins differed in their primary sequences and only showed homology to one another. The toxin purified from T. flavoviridis revealed this toxin to be flavocetin-A, a heterodimeric CLRP which had so far only been shown to have GPIb-binding activity. At the time of flavocetin-A’s purification, flavocetin-B was co-purified; flavocetin-B consists of the same two α and β subunits, plus an additional γ subunit. As no sequence information is known to date for the γ subunit, it may be one of the additional proteins purified here, along with an additional δ subunit. Therefore, the toxin isolated here may actually consist of four different subunits forming a tetramer of two different heterodimers, generating an (αβ)2(γδ)2 structure. This proposed (αβ)2(γδ)2 flavocetin-A structure has binding sites for both α2β1 integrin and GPIb, with no sterical overlap, as shown by affinity chromatography using the α2A domain and the extracellular domain of the GPIb receptor. The potential of VP-i and flavocetin-A to inhibit integrin-binding to type I collagen was shown during purification: Both toxins efficiently bind to the integrin α2A domain; also, VP-i and vixapatin bind to the A domain with the same affinity. Surface plasmon resonance showed the interaction of flavocetin-A with the α2β1 integrin to be extremely strong and association to be very fast. Furthermore, both toxins were shown to inhibit binding of the wildtype integrin to collagen: VP-i and flavocetin-A acted antagonistically on cell adhesion and cell migration. Initially, the interaction between VP-i and α2β1 integrin was to be further characterized with the help of monoclonal antibodies. However, this proved problematic, the procedure requiring various optimizations. Although, after expert consultation, some monoclonal antibodies could be obtained, the cells were extremely sensitive and gave unsatisfactory results when tested as detection tools in Western blot and immunoassays. Concluding, two novel α2β1 integrin inhibitors were discovered: VP-i and flavocetin-A, which were purified using the same procedure and which have similar functions. Both are Ctype lectin-related proteins which effectively inhibit cell adhesion and migration. This underlines that nature has instrumentalized CLRPs to specifically inhibit α2β1 integrin. Further characterization of VP-i and flavocetin-A will be able to provide leads for future drug development.
In this thesis the integral membrane protein diacylglycerol kinase (DAGK) from E.coli is investigated with solid-state NMR. The aim is to gain an insight into the enzyme’s mechanism through integration of kinetic, structural and dynamic data. The biological function of DAGK is the transfer of the γ-phosphate group from Mg*ATP to diacylglycerol (DAG) building phosphatidic acid (PA)[6] as port of the membrane-derived oligosaccharide cycle[31,34]. Surprisingly, DAGK does not share structural or sequential similarities with other kinases[12]. Typical sequence motives found in other kinases, which catalyze phosphoryl transfer reactions, are not found[13]. In its physiological form DAGK is a homo-trimer with nine transmembrane helices, three catalytic centers and a size of 39.6 kDa.
First, the set-up of a real-time 31P MAS NMR experiment is shown. This experiment allows measuring in real-time the simultaneous ATP hydrolysis in the aqueous phase and lipid substrate phos-phorylation in the membrane phase with atomic resolution under magic angle spinning[56]. After fast transfer of the sample into the NMR spectrometer the enzymatic reaction is started with a temperature jump. This approach of real-time MAS NMR in a dual-phase system was demonstrated for the lipid substrate analogs dioleoyl- (DOG) and dibutyrylglycerol (DBG), with a C8 and C4 aliphatic chain, respectively. The combination of 31P direct and cross polarization functions as a dynamic filter. In the 31P direct polarized experiment nuclei in both phases are detected, while in the 31P cross polar-ized experiment, only nuclei in the membrane phase are detected. Rates for substrate turnover, i.e. degradation of γP-, βP, αP-ATP and build-up of βP-, αP-ADP, free phosphate as side reaction, and PA are obtained, which reveal a Michaelis-Menten behavior with regard to Mg*ATP and DBG. Here Mg*ATP and DBG follow a random-equilibrium model, where every substrate can bind indepen-dently from the other substrate. Analyses of the peak integrals from educts and products of the enzymatic reaction, revealed the stoichiometry of the reaction: 1.5 ATP molecules are used to phos-phorylate one DBG molecule. The excess of ATP is attributed to the basal ATPase activity. Further-more, experiments with ATPγS, usually regarded as a non-hydrolysable ATP-analog, where carried out. Surprisingly, DAGK hydrolyzes ATPγS and also transfers the thio-phosphate group to the lipid acceptor DBG, which points to a certain degree of plasticity in the active center. A phosphorylated enzyme intermediate was not detected. These results suggest the building of a ternary complex of Mg*ATP, DBG and DAGK performing a direct-phosphoryl transfer reaction, without passing through a phosphorylated enzyme intermediate. Experiments with the transition state analog ortho-vanadate (Vi) showed a decoupling of the ATP hydrolysis activity from lipid substrate phosphorylation. This indicates a specific transfer site for the γ-phosphate group from ATP to DAG, which can be blocked by Vi.
A general disadvantage of NMR spectroscopy compared to other spectroscopic methods is its inherent low sensitivity. One possible starting point for the improvement of signal-to-noise per unit time is the reduction of the spin-lattice relaxation time of protons[209]. Usually 95 % of the experi-mental time is required for the relaxation of the 1H to equilibrium. The addition of paramagnetic species can be used to reduce the 1H T1[233]. In a comprehensive study four different paramagnetic agents were tested: Cu2+-EDTA, Cu2+-EDTA-tag, Gd3+-TTAHA and Gd3+-DOTA. The titration of these paramagnetic complexes showed the principle feasibility of this approach, but differences between the tested species exist. The most promising complex is Gd3+-DOTA which, at a concentration of 2 mM, causes a 10-time improvement of signal-to-noise ratio per unit time. This allowed measuring 2D 13C-13C correlation spectra of proteoliposomes in one tenth of the usual required experimental time (i.e. 10 hours vs. 4 days) with good signal-to-noise.
For the investigation of structural or dynamic changes in the protein upon substrate interaction with MAS NMR, the spectral properties CP efficiency and resolution of the DAGK in liposomes needed to be improved. The most critical step during sample preparation is the reconstitution of the membrane protein from detergent micelles into a membrane of synthetic lipids under detergent removal. For this procedure the important criteria are enzymatic activity, measured in a coupled ATPase assay[55], and homogeneity of the proteoliposomes, which was tested e.g. on a discontinuous sucrose step gradient. Therefore an extensive study was carried out, in which different detergents, lipids and lipid mixtures, techniques for detergent removal and different protein-to-lipid ratios were tested. A direct correlation between high ATPase activity and good resolution was not found. Moreover, active DAGK in a mixture of DMPC and cholesterol, which emulates the membrane features of a membrane containing DAG, showed the best CP efficiency and resolution.
The assignment of the protein backbone and amino acid side chains the first mandatory step towards the investigation of structural and dynamical features influencing and defining the enzymatic mechanism by MAS NMR. As the assignment procedure is very time consuming for a total protein, a special labeling scheme for DAGK was developed, which allows assigning most of the protein areas presumably involved in enzyme catalysis. The assignment of DAGK with solution NMR[132] was not transferable to the MAS NMR spectra. Most important for the assignment process were the unique pairs[335], two consecutive amino acids which only appear once in the amino acid sequence. These unique pairs served as anchor points. Five different multinuclear MAS NMR experiments (DARR, NCO, NCA, NCACX, NCOCX) were required for the sequential assignment. It was possible to assign 35 % of the total amino acid sequence with one sample and 8 experiments acquired at 850 MHz. The secondary structure analysis showed subtle differences to the DAGK assignment with solution NMR[132], which can be attributed to the different environment in lipid bilayers and detergent micelles.
Data about structural and dynamical changes under substrate interaction can reveal details about the enzymatic mechanism. Therefore changes in chemical shift in 2D heteronuclear correlation experiments in the apo-state and under substrate saturated conditions with the substrates Mg*AMP-PNP, a non-hydrolysable ATP-analog, DOG, a mixture of Mg*AMP-PNP and DOG as well as inhibited by Vi were recorded. The most significant peak changes were observed at the interface membrane-cytoplasm as well as the the N-terminal amphipathic helix. The residues revealing chemical shift perturbations correlate with conserved residues or such residues, for which importance for catalysis and/or folding could be shown in mutation studies[8]. Especially noticeable were the changes at the amino acids Asn 72, Lys 64, His 87, Tyr 86 and Asp 95.
Beside changes of the chemical shift, changes of line width or signal doubling were observable. These changes can point to a correlation with dynamic reorientations in the μs-ms time regime, which are most relevant for enzymatic processes. The protein backbone dynamics in the apo-state as well as saturated with the substrates or inhibited with Vi were investigated with a 15N-CODEX experiment, which is based on the reorientation of the CSA tensor upon dynamical changes[350]. Specific effects of the different substrates or analogs on the protein backbone dynamic were revealed complementing the structural data and the chemical shift perturbation experiments.
Retroviral vectors are powerful tools in clinical gene therapy as they integrate permanently into the target cell genome and thus guarantee long-term expression of transgenes. Therefore, they belong to the most frequently used application platforms in clinical gene therapy involving a broad range of different target cells and tissues. However, stable genomic integration of retroviral vectors can be oncogenic, as reported in several animal models and in clinical trials. In particular, γ-retroviral vectors, which derive from naturally mutagenic γ-retroviruses, integrate semirandomly into the host genome with regard to the target sequence, but have a preference for regions of active transcription and regulatory elements of transcriptionally active genes. The integration can result in overexpression of adjacent genes or disruption of ‘target’ gene expression. Moreover, γ-retroviral integration can cause modified transcripts and proteins through alternative or aberrant splicing or through premature termination of transcription.
Initially, the event of insertional mutagenesis and subsequent induction of leukemia by the genotoxicity of a γ-retroviral vector was described in a mouse model after genetic modification of hematopoietic stem cells (HSCs). Vector-related activation and overexpression of the oncogene ecotropic viral integration site-1 (Evi1) fostered clonal outgrowth and leukemogenesis. Additional genotoxic events of γ-retroviral vectors were observed in clinical HSC gene therapy trials for X-linked severe combined immune deficiency (SCID-X1), chronic granulomatous disease (X-CGD), and Wiskott-Aldrich Syndrome (WAS). But, genotoxicity induced by γ-retroviral vectors has never been described in clinical gene therapy trials involving adoptive transfer of genetically modified mature T lymphocytes. This fact is surprising, since T cells are long-lived and have a high capacity of self-renewal.
In a previous study, the susceptibility towards oncogenic transformation of mature T cells and HSCs after genetic modification was compared. It could be demonstrated that T-cell receptor (TCR)-polyclonal mature T cells are far less prone to transformation after γ-retroviral transfer of (proto-)oncogenes in vivo than HSCs. Additional experiments revealed that TCR-oligoclonal (OT-I and P14) mature T cells are transformable in the same setting and give rise to mature T-cell lymphomas (MTCLs).
In the present thesis, the susceptibility of mature T cells towards insertional mutagenesis was investigated. Within the first part of the thesis, retroviral integration sites (RISs) from 33 murine MTCLs were retrieved and subsequently analyzed in terms of integration pattern, detection of common integration sites (CIS) and gene ontology (GO). As these bioinformatic results demonstrated that insertional mutagenesis most likely contributed to mature T-cell lymphomagenesis, the susceptibility of mature T cells was directly assessed in a mouse model. Therefore, murine TCR-oligoclonal OT-I T cells were transduced with an enhanced green fluorescent protein (EGFP) encoding γ-retroviral vector and gene-modified T cells were transplanted into RAG1-/- mice. After 16 months, including one round of serial transplantation, a case of MTCL emerged. Tumor cells were characterized by CD3, CD8, TCR and ICOS expression. Integration site analysis via ligation-mediated polymerase chain reaction (LM-PCR) revealed a proviral insertion in the Janus kinase 1 (Jak1) gene. Subsequent overexpression of Jak1 could be demonstrated on transcriptional and protein level. Furthermore, T-cell lymphoma cells were characterized by an activated Jak/STAT-pathway as signal transducer and activator of transcription 3 (STAT3) was highly phosphorylated. The overexpression of Jak1 was causally implicated in tumor growth promotion as specific pharmacological inhibition of Jak1 using Ruxolitinib significantly prolonged survival of mice transplanted with these Jak1-activated tumor cells. A concluding systematic metaanalysis of available gene expression data on human mature T-cell lymphomas/leukemias confirmed the relevance of Jak/STAT overexpression in sporadic human T-cell tumorigenesis.
This was the first reported case of an insertional mutagenesis event in mature T cells in vivo. Thus, the results obtained in this thesis underline the importance of long-term monitoring of genetically modified T cells in vivo and the evaluation of vector toxicology and safety in T-cell based gene therapies. In particular, the transduction of T cells with a recombinant TCR or CAR (chimeric antigen receptor) bears a risk enhancement, as normal T-cell homeostasis is perturbed besides the general risk of insertional mutagenesis.
In the absence of apparent mutations, alteration of gene expression patterns represents the key mechanism by which normal cells evolve to cancer cells.
Gene expression is tightly regulated by posttranscriptional processes. Within this context, RNA-binding proteins (RBPs) represent fundamental factors, since they control mechanisms, such as mRNA-stabilization, -translation and -degradation. Human antigen R (HuR) was among the first RBPs that have been directly associated to carcinogenesis. HuR modulates the stability and translation of mRNAs which encode proteins facilitating various ‘hallmarks of cancer’, namely proliferation, evasion of growth suppression, angiogenesis, cell death resistance, invasion and metastasis. Furthermore, it is well established that tumor-promoting inflammation contributes to tumorigenesis. In this process, monocytes are attracted to the site of the tumor and educated towards a tumor-promoting macrophage phenotype. While HuR has been extensively studied in various tumor cell types, little is known about HuR in hepatocellular carcinoma (HCC). Thus, the aim of my work was to characterize the contribution of HuR to the development of cancer characteristics in HCC. I was particularly interested to investigate if HuR facilitates tumor-promoting inflammation, since a role for HuR has not been described in this context. To this end, I depleted HuR in HepG2 cells (HuR k/d) and used a co-culture model of HepG2 tumor spheroids and infiltrating monocytes to study the impact of HuR on the tumor microenvironment. I could show that depletion of HuR resulted in the reduction of cell numbers. Additionally, the expression of proliferation marker KI-67 and proto-oncogene c-Myc was reduced, supporting a proliferative role of HuR. Furthermore, exposure to cytotoxic staurosporine elevated apoptosis in HuR k/d cells compared to control cells. Concomitantly, the expression of the anti-apoptotic mediator B-cell lymphoma protein-2 (Bcl-2) was markedly reduced in the HuR k/d cells, pointing to an involvement of HuR in cell survival processes.
Accordingly, a pro-survival function of HuR was also observed in tumor spheroids, since HuR k/d spheroids exhibited a larger necrotic core region at earlier time points and showed elevated numbers of dead cells compared to control (Ctr.) spheroids. Interestingly, HuR k/d spheroids isplayed reduced numbers of infiltrated macrophages, suggesting that HuR contributes to a tumor-promoting, inflammatory microenvironment by recruiting monocytes/macrophages to the tumor site. Aiming at identifying HuR-regulated factors responsible for the recruitment of monocytes, I found reduced levels of the chemokine interleukin 8 (IL-8) in supernatants of HuR k/d spheroids, supporting a critical involvement of HuR in the chemoattraction of monocytes. Analyzing supernatants of co-cultures of macrophages and HuR k/d or Ctr. spheroids revealed additional differences in chemokine secretion patterns. Interestingly, protein levels of many chemokines were elevated in co-cultures of HuR k/d spheroids compared to control co-cultures. Albeit enhanced chemokine secretion was observed, less monocytes are recruited into HuR k/d spheroids, further underlining the necessity of HuR in cancer related monocyte/macrophage attraction and infiltration. Differences between chemokine profiles of mono- and co-cultured spheroids could be attributable to changes in spheroid-derived chemokines as a result of the crosstalk with the immune cells. Provided the chemokines originate from monocytes/macrophages, the different secretion patterns suggest that HuR contributes to the modulation of the functional phenotype of infiltrated macrophages, since the tumorenvironment is critically involved in the shaping of macrophage phenotypes. Regions of low-oxygen (hypoxia) represent another critical feature of tumors. Therefore, I next analyzed the impact of HuR on the hypoxic response. Loss of HuR attenuated hypoxia-inducible factor (HIF) 2α expression after exposure to hypoxia, while HIF-1α protein levels remained unaltered. Considering previous results of our group, showing that HIF-2α depletion (HIF-2α k/d) resulted in the enhanced expression of HIF-1α protein, I aimed to determine the involvement of HuR in the compensatory upregulation of HIF-1α protein in HIF-2α k/d cells. I could demonstrate that not only total HuR protein levels, but specifically cytoplasmic HuR was elevated in HIF-2α depleted cells pointing to enhanced HuR activity. Silencing HuR in HIF-2α deficient cells attenuated enhanced HIF-1α protein expression, thus confirming a direct role of HuR in the compensatory upregulation of HIF-1α. This as also reflected on HIF-1α target gene expression. I further investigated the mechanism underlying the compensatory HIF-1α expression in HIF-2α deficient cells. Analyzing HIF-1α mRNA expression, I excluded enhanced HIF1-α transcription and stability to account for elevated HIF-1α expression in HIF-2α k/d cells. HIF-1α promoter activity assays confirmed the mRNA data. Furthermore, HIF-1α protein half-life was not elevated in HIF-2α k/d cells compared to control cells, indicating that HIF-1α protein stability is not altered in HIF-2α k/d cells. Analysis of the association of HIF-1α with the translational machinery using polysomal fractionation finally revealed an increased istribution of HIF-1α mRNA in the heavier polysomal fractions in HIF-2α k/d cells compared to control cells. Since augmented ribosome occupancy is an indicator for more efficient translation, I propose enhanced HIF-1α translation as underlying principle of the compensatory increase in HIF-1α protein levels in HIF-2α k/d cells. In summary, my results demonstrate that HuR is critical for the development of cancer characteristics in HCC. Future work analyzing the impact of HuR on tumor-promoting inflammation, specifically macrophage attraction and activation could provide new trategies to inhibit macrophage-driven tumor progression. Furthermore, I provide evidence that HuR contributes to the hypoxic response by regulating the expression of HIF-1α and HIF-2α. Targeting single HIF-isoforms for tumor therapy should be carefully considered, because of their compensatory regulation when one α-subunit is depleted. Thus, therapeutic strategies targeting factors such as HuR that control both α-subunits and at the same time prevent compensation might be more promising.
Plants absorb sunlight via photosynthetic pigments and convert light energy intochemical energy in the process of photosynthesis. These pigments are mainly bound to antenna protein complexes that funnel the excitation energy to the photosynthetic reaction centres. The peripheral antenna of plant photosystem II (PSII) consists of the major light-harvesting complex of PSII (LHC-II) and the minor LHCs CP29, CP26 and CP24. Light intensity can change frequently and plants need to adapt to high-light conditions in order to avoid photodamage. When more photons are absorbed than can be utilised by the photosynthetic machinery, excessive excitation energy is dissipated as heat by short-term adaptation processes collectively known as non-photochemical quenching (NPQ). A decrease in PSII antenna chlorophyll (Chl) fluorescence yield and a reduction in the average Chl fluorescence lifetime are associated with NPQ. The main component of NPQ is the so-called energy-dependent quenching (qE), and it is triggered by the rapid drop in thylakoid lumenal pH resulting from the plant’s photosynthetic activity. This process is thought to take place at the PSII antenna complexes, which therefore not only capture and transfer light energy but are also involved in balancing the energy flow. The decrease in lumenal pH acivates the enzyme violaxanthin de-epoxidase (VDE), which converts the xanthophyll violaxanthin (Vio) into zeaxanthin (Zea) in the xanthophyll cycle. In addition, the PSII subunit PsbS was discovered to be essential for qE by screening qE-deficient Arabidopsis thaliana mutants. This membrane protein is considered a member of the LHC superfamily, which also includes LHC-II and the minor LHCs. Previous studies on PsbS isolated either from native source or refolded in vitro have produced inconsistent results on its pigment binding capacity. Interestingly, a pH-dependent change in the quaternary structure of PsbS under high light conditions has been reported. This observed dimer-tomonomer transition very likely follows the protonation of lumenal glutamates upon the drop in pH and is accompanied by a change in PSII supercomplex localisation. PsbS dimers are preferentially found in association with the PSII core, whereas PsbS monomers co-localise with LHC-II.Despite the identification of !pH, Zea and PsbS as key players in qE, both the nature of the quencher(s) as well as the underlying molecular mechanism leading to excess energy dissipation still remain unknown. Several models have been put forward to explain the reversible switch in the antenna from an energy-transmitting to a quenched state. Proposals include a simple pigment exchange of Vio for Zea, and aggregation or an internal conformational change of LHC-II. Charge transfer (CT)quenching in the minor LHCs or quenching by carotenoid dark state (Car S1)-Chl interactions have also been suggested. However, none of these qE models has so far been capable of accommodating all the physiological observations and available experimental data. Most importantly, the function of PsbS remains an enigma. A recent qE model suggested that monomerisation of PsbS enables the protein to transiently bind a carotenoid and form a quenching unit with a Chl of a PSII LHC. In view of the various proposed qE mechanisms, this thesis aimed at understanding the interplay of the different qE components and the contribution of the PSII subunits LHC-II, the minor LHCs and PsbS to qE. The initial approach was to investigate the properties of the PSII subunits in the most simple in vitro model system, namely in detergent solution. For this purpose, LHC-II was isolated either from native source or refolded from recombinantly produced protein. Investigation of the minor LHCs and PsbS required heterologous expression and refolding. In addition, experiments were performed on aggregated LHC-II. Aggregates of LHC-II have been used as a popular model system for qE because they exhibit highly quenched Chl fluorescence. At the final stage of this doctoral work, a more sophisticated model system to approximate the thylakoid membrane was developed by reconstitution of the PSII subunits LHC-II and PsbS into liposomes. This system not only allowed for investigation of these membrane proteins in their native environment, but also for mimicking the xanthophyll cycle by distribution of Zea within the membrane as well as !pH by outside buffer exchange. The role of Zea in qE was first investigated with detergent solubilised antenna proteins. The requirement of this xanthophyll for qE is well-known, but the specific contribution to the molecular quenching mechansim is unclear. Previous work had shown that replacement of Vio for Zea in LHC-II was not sufficient to induce Chl fluorescence quenching in Zea-LHC-II, as suggested by the so-called molecular gearshift mechanism. However, by means of selective two-photon excitation spectroscopy, an increase in electronic interactions between Car S1 and Chls was observed for LHC-II upon lowering the pH of the detergent buffer. Electronic Car S1-Chl coupling became even stronger when Zea-LHC-II was probed. The extent of Car S1-Chl coupling correlated directly with the extent of Chl fluorescence quenching, in a similar way as observed previously in live plants under high-light conditions. However, very similar results were obtained with LHC-II aggregates. This implied that the increase in electronic interactions and fluorescence quenching was independent of Zea and low pH. Further experiments on aggregates of LHC-II Chl mutants indicated that the targeted pigments were also not essential for the observed effects. It is proposed that the same molecular mechanism causes an increase in electronic Car S1-Chl interactions and Chl fluorescence quenching in Zea-LHC-II at low pH as well as in aggregated LHC-II. Most likely, surface exposed pigments form random quenching centres in both cases. On the other hand, it was possible that Zea could act as a direct quencher of excess excitation energy in the minor LHCs. However, enrichment of refolded CP29, CP26 and CP24 with Zea did not lead to a change in the Chl excited state lifetime. Formation of a carotenoid radical cation, previously implied in CT quenching, was also not observed, although artificial generation of such a radical cation was principally possible as shown for CP29. During the course of this work, a study reporting the formation of Zea radical cations in minor LHCs was published. Therefore, Zea-enriched minor LHCs were again investigated on the experimental apparatus used in the reported study. Indeed, the presence of at least one carotenoid radical cation for each minor complex was detected. It is suggested that either the preparation method of incubating the refolded minor LHCs with Zea in contrast to refolding the complexes with only Zea and lutein causes the observed differences or that the observed spectral radical cation signatures are due to experimental artifacts. While the experiments with LHC-II and the minor LHCs gave useful insights into the putative qE mechanism, the quencher site and the mode of action of Zea could still not be unambiguously identified. Most importantly, these studies could not explain the function of the qE keyplayer PsbS. Therefore, the focus of the work was shifted to PsbS protein production, purification and characterisation. In view of inconsistent reports on the pigment binding capacity of this PSII subunit, refolding trials with and without photosynthetic pigments were conducted. The formation of a specific pigmentprotein complex typical for other LHCs was not observed and neither was the earlier reported “activation” of Zea for qE by binding to this protein. Nevertheless, PsbS refolded without pigments displayed secondary structure content in agreement with previous studies, indicating pigment-independent folding. Reconstitution of pigmentfree, refolded PsbS into liposomes confirmed that the protein is stable in the absence of pigments. Zea distributed in PsbS-containing liposomes also showed no spectral alteration that would indicate its “activation”. With the ability to reconstitute PsbS, it was then possible to proceed to modelling qE in a proteoliposome system. For this purpose, PsbS was co-reconstituted with LHC-II, which has been reported to interact with PsbS. One-photon excitation (OPE) and two-photon excitation (TPE) spectroscopy measurements were performed on LHC-II- and LHC-II/PsbS-containing liposomes. This enabled both quantification of Chl fluorescence quenching as well as determination of the extent of electronic Car S1-Chl interactions. The effect of Zea was investigated by incorporating it in the proteoliposome membrane. It was shown that Zea alone was not able to induce significant Chl fluorescence quenching when only LHC-II was present. However, when LHC-II and PsbS were co-reconstituted, pronounced Chl fluorescence quenching and an increase in electronic Car S1-Chl interactions were observed and both effects were enhanced when Zea was present. Western blot analysis indicated the presence of a LHC-II/PsbS-heterodimer in these proteoliposomes. In addition to the OPE and TPE measurements, the average Chl fluorescence lifetime was determined in detergent-free buffer at neutral pH and directly after buffer exchange to low pH. No significant changes in the average lifetime were observed for LHC-II proteoliposomes when either Zea was present or after exchange for low pH buffer. This indicated that Zea alone cannot act as a direct quencher, which concurs with the OPE measurements. Moreover, the complex was also properly reconstituted as no aggregation or significant Chl fluorescence quenching were observed. The average lifetime was not significantly affected in LHC-II/PsbS-proteoliposomes, independent of Zea or pH. However, a shortlived component in the presence of a long-lived component was not resolvable with the time resolution of the fluorescence lifetime apparatus.
Implications for qE model systems and the in vivo quenching mechanism are discussed based on the experiments in detergent solution, on LHC-II aggregates and with the proteoliposome model system.