965 resultados para conformational
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Carbohydrates are a complex group of biomolecules with a high structural diversity. Their almost omnipresent occurrence has generated a broad field of research in both biology and chemistry. This thesis focuses on three different aspects of carbohydrate chemistry, synthesis, structure elucidation and the conformational analysis of carbohydrates. The first paper describes the synthesis of a penta- and a tetrasaccharide related to the highly branched capsular polysaccharide from Streptococcus pneumoniae type 37. In the second paper, the structure of the O-antigenic repeating unit from the lipopolysaccharide of E. coli 396/C1 was determined along with indications of the structure of the biological repeating unit. In addition, its structural and immunological relationship with E. coli O126 is discussed. In the third paper, partially protected galactopyranosides were examined to clarify the origin of an intriguing 4JHO,H coupling, where a W-mediated coupling pathway was found to operate. In the fourth paper, the conformation of methyl a-cellobioside is studied with a combination of molecular dynamics simulations and NMR spectroscopy. In addition to the expected syn-conformation, detection and quantification of anti-ø and anti-ψ conformers was also possible.
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In this thesis we focussed on the characterization of the reaction center (RC) protein purified from the photosynthetic bacterium Rhodobacter sphaeroides. In particular, we discussed the effects of native and artificial environment on the light-induced electron transfer processes. The native environment consist of the inner antenna LH1 complex that copurifies with the RC forming the so called core complex, and the lipid phase tightly associated with it. In parallel, we analyzed the role of saccharidic glassy matrices on the interplay between electron transfer processes and internal protein dynamics. As a different artificial matrix, we incorporated the RC protein in a layer-by-layer structure with a twofold aim: to check the behaviour of the protein in such an unusual environment and to test the response of the system to herbicides. By examining the RC in its native environment, we found that the light-induced charge separated state P+QB - is markedly stabilized (by about 40 meV) in the core complex as compared to the RC-only system over a physiological pH range. We also verified that, as compared to the average composition of the membrane, the core complex copurifies with a tightly bound lipid complement of about 90 phospholipid molecules per RC, which is strongly enriched in cardiolipin. In parallel, a large ubiquinone pool was found in association with the core complex, giving rise to a quinone concentration about ten times larger than the average one in the membrane. Moreover, this quinone pool is fully functional, i.e. it is promptly available at the QB site during multiple turnover excitation of the RC. The latter two observations suggest important heterogeneities and anisotropies in the native membranes which can in principle account for the stabilization of the charge separated state in the core complex. The thermodynamic and kinetic parameters obtained in the RC-LH1 complex are very close to those measured in intact membranes, indicating that the electron transfer properties of the RC in vivo are essentially determined by its local environment. The studies performed by incorporating the RC into saccharidic matrices evidenced the relevance of solvent-protein interactions and dynamical coupling in determining the kinetics of electron transfer processes. The usual approach when studying the interplay between internal motions and protein function consists in freezing the degrees of freedom of the protein at cryogenic temperature. We proved that the “trehalose approach” offers distinct advantages with respect to this traditional methodology. We showed, in fact, that the RC conformational dynamics, coupled to specific electron transfer processes, can be modulated by varying the hydration level of the trehalose matrix at room temperature, thus allowing to disentangle solvent from temperature effects. The comparison between different saccharidic matrices has revealed that the structural and dynamical protein-matrix coupling depends strongly upon the sugar. The analyses performed in RCs embedded in polyelectrolyte multilayers (PEM) structures have shown that the electron transfer from QA - to QB, a conformationally gated process extremely sensitive to the RC environment, can be strongly modulated by the hydration level of the matrix, confirming analogous results obtained for this electron transfer reaction in sugar matrices. We found that PEM-RCs are a very stable system, particularly suitable to study the thermodynamics and kinetics of herbicide binding to the QB site. These features make PEM-RC structures quite promising in the development of herbicide biosensors. The studies discussed in the present thesis have shown that, although the effects on electron transfer induced by the native and artificial environments tested are markedly different, they can be described on the basis of a common kinetic model which takes into account the static conformational heterogeneity of the RC and the interconversion between conformational substates. Interestingly, the same distribution of rate constants (i.e. a Gamma distribution function) can describe charge recombination processes in solutions of purified RC, in RC-LH1 complexes, in wet and dry RC-PEM structures and in glassy saccharidic matrices over a wide range of hydration levels. In conclusion, the results obtained for RCs in different physico-chemical environments emphasize the relevance of the structure/dynamics solvent/protein coupling in determining the energetics and the kinetics of electron transfer processes in a membrane protein complex.
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This Ph.D. candidate thesis collects the research work I conducted under the supervision of Prof.Bruno Samor´ı in 2005,2006 and 2007. Some parts of this work included in the Part III have been begun by myself during my undergraduate thesis in the same laboratory and then completed during the initial part of my Ph.D. thesis: the whole results have been included for the sake of understanding and completeness. During my graduate studies I worked on two very different protein systems. The theorical trait d’union between these studies, at the biological level, is the acknowledgement that protein biophysical and structural studies must, in many cases, take into account the dynamical states of protein conformational equilibria and of local physico-chemical conditions where the system studied actually performs its function. This is introducted in the introductory part in Chapter 2. Two different examples of this are presented: the structural significance deriving from the action of mechanical forces in vivo (Chapter 3) and the complexity of conformational equilibria in intrinsically unstructured proteins and amyloid formation (Chapter 4). My experimental work investigated both these examples by using in both cases the single molecule force spectroscopy technique (described in Chapter 5 and Chapter 6). The work conducted on angiostatin focused on the characterization of the relationships between the mechanochemical properties and the mechanism of action of the angiostatin protein, and most importantly their intertwining with the further layer of complexity due to disulfide redox equilibria (Part III). These studies were accompanied concurrently by the elaboration of a theorical model for a novel signalling pathway that may be relevant in the extracellular space, detailed in Chapter 7.2. The work conducted on -synuclein (Part IV) instead brought a whole new twist to the single molecule force spectroscopy methodology, applying it as a structural technique to elucidate the conformational equilibria present in intrinsically unstructured proteins. These equilibria are of utmost interest from a biophysical point of view, but most importantly because of their direct relationship with amyloid aggregation and, consequently, the aetiology of relevant pathologies like Parkinson’s disease. The work characterized, for the first time, conformational equilibria in an intrinsically unstructured protein at the single molecule level and, again for the first time, identified a monomeric folded conformation that is correlated with conditions leading to -synuclein and, ultimately, Parkinson’s disease. Also, during the research work, I found myself in the need of a generalpurpose data analysis application for single molecule force spectroscopy data analysis that could solve some common logistic and data analysis problems that are common in this technique. I developed an application that addresses some of these problems, herein presented (Part V), and that aims to be publicly released soon.
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Akt (also called PKB) is a 63 kDa serine/threonine kinase involved in promotion of cell survival, proliferation a nd metabolic responses downstream the phosphoinositide-3-kinase (PI 3-kinase) signaling pathway. In resting cells, Akt is a predominantly cytosolic enzyme; however generation of PI 3-kinase lipid products recruits Akt to the plasma membrane, resulting in a conformational change which confers full enzymatic activity through the phosphorylation of the membrane-bound protein at two residues, Thr308, and Ser473. Activated Akt redistributes to cytoplasm and nucleus, where phosphorylation of specific substrates occurs. Both the presence and the activity of Akt in the nucleus have been described. An interesting mechanism that mediates nuclear translocation of Akt has been described in human mature T-cell leukemia: the product of TCL1 gene, Tcl1, interacts with the PH domain of phosphorylated Akt, thus driving Akt to the nucleus. In this context, Tcl1 may act as a direct transporter of Akt or may contribute to the formation of a complex that promotes the transport of active Akt to the nucleus, where it can phosphorylate nuclear substrates. A well described nuclear substrate if Foxo. IGF-1 triggers phosphorylation of Foxo by Akt inside the nucleus, where phospho-Foxo associates to 14.3.3 proteins that, in turn, promote its export to the cytoplasm where it is sequestered. Remarkably, Foxo phosphorylation by Akt has been shown to be a crucial event in Akt-dependent myogenesis. However, most Akt nuclear substrates have so far remained elusive, as well as nuclear Akt functions. This lack of information prompted us to undertake a search of substrates of Akt in the nucleus, by the combined use of 2D-separation/mass spectrometry and anti-Akt-phosphosubstrate antibody. This study presents evidence of A-type lamins as novel nuclear substrates of Akt. Lamins are type V intermediate filaments proteins found in the nucleus of higher eukaryotes where, together with lamin-binding proteins, they form the lamina at the nuclear envelope, providing mechanical stability for the nuclear membrane. By coimmunoprecipitation, it is demonstrated here that endogenous lamin A and Akt interact, and that A-type lamins are phosphorylated by Akt both in vitro and in vivo. Moreover, by phosphoaminoacid analysis and mutagenesis, it is further demonstrated that Akt phosphorylates lamin A at Ser404, and, more importantly, that while lamin A/C phosphorylation is stable throughout the cell cycle, phosphorylation of the precursor prelamin A becomes detectable as cells enter the G2 phase, picking at G2/M. This study also shows that lamin phosphorylation by Akt creates a binding site for 14.3.3 adaptors which, in turn, promote prelamin A degradation. While this mechanism is in agreement with a general role of Akt in the regulation of a subset of its substrates, opposite to what has been described, degradation is not mediated through a ubiquitination and proteasomal mechanism but through a lysosomal pathway, as indicated by the reverting action of the lysosomal inhibitor cloroquine. Phosphorylation is a key event in the mitotic breakdown of the nuclear lamina. However, the kinases and the precise sites of phosphorylation are scarcely known. Therefore, these results represent an important breakthrough in this very significant but understudied area. The phosphorylation of the precursor protein prelamin A and its subsequent degradation at G2/M, when both the nuclear envelop and the nuclear lamina disassemble, can be view as part of a mechanism to dispose off the precursor that is not needed in this precise context. The recently reported finding that patients affected by Emery-Dreifuss muscular dystrophy carry a mutation at Arg 401, in the Akt phosphorylation motif, open new perspective that warrant further investigation in this very important field.
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The aim of this Ph.D. project has been the design and characterization of new and more efficient luminescent tools, in particular sensors and labels, for analytical chemistry, medical diagnostics and imaging. Actually both the increasing temporal and spatial resolutions that are demanded by those branches, coupled to a sensitivity that is required to reach the single molecule resolution, can be provided by the wide range of techniques based on luminescence spectroscopy. As far as the development of new chemical sensors is concerned, as chemists we were interested in the preparation of new, efficient, sensing materials. In this context, we kept developing new molecular chemosensors, by exploiting the supramolecular approach, for different classes of analytes. In particular we studied a family of luminescent tetrapodal-hosts based on aminopyridinium units with pyrenyl groups for the detection of anions. These systems exhibited noticeable changes in the photophysical properties, depending on the nature of the anion; in particular, addition of chloride resulted in a conformational change, giving an initial increase in excimeric emission. A good selectivity for dicarboxylic acid was also found. In the search for higher sensitivities, we moved our attention also to systems able to perform amplification effects. In this context we described the metal ion binding properties of three photoactive poly-(arylene ethynylene) co-polymers with different complexing units and we highlighted, for one of them, a ten-fold amplification of the response in case of addition of Zn2+, Cu2+ and Hg2+ ions. In addition, we were able to demonstrate the formation of complexes with Yb3+ an Er3+ and an efficient sensitization of their typical metal centered NIR emission upon excitation of the polymer structure, this feature being of particular interest for their possible applications in optical imaging and in optical amplification for telecommunication purposes. An amplification effect was also observed during this research in silica nanoparticles derivatized with a suitable zinc probe. In this case we were able to prove, for the first time, that nanoparticles can work as “off-on” chemosensors with signal amplification. Fluorescent silica nanoparticles can be thus seen as innovative multicomponent systems in which the organization of photophysically active units gives rise to fruitful collective effects. These precious effects can be exploited for biological imaging, medical diagnostic and therapeutics, as evidenced also by some results reported in this thesis. In particular, the observed amplification effect has been obtained thanks to a suitable organization of molecular probe units onto the surface of the nanoparticles. In the effort of reaching a deeper inside in the mechanisms which lead to the final amplification effects, we also attempted to find a correlation between the synthetic route and the final organization of the active molecules in the silica network, and thus with those mutual interactions between one another which result in the emerging, collective behavior, responsible for the desired signal amplification. In this context, we firstly investigated the process of formation of silica nanoparticles doped with pyrene derivative and we showed that the dyes are not uniformly dispersed inside the silica matrix; thus, core-shell structures can be formed spontaneously in a one step synthesis. Moreover, as far as the design of new labels is concerned, we reported a new synthetic approach to obtain a class of robust, biocompatible silica core-shell nanoparticles able to show a long-term stability. Taking advantage of this new approach we also showed the synthesis and photophysical properties of core-shell NIR absorbing and emitting materials that proved to be very valuable for in-vivo imaging. In general, the dye doped silica nanoparticles prepared in the framework of this project can conjugate unique properties, such as a very high brightness, due to the possibility to include many fluorophores per nanoparticle, high stability, because of the shielding effect of the silica matrix, and, to date, no toxicity, with a simple and low-cost preparation. All these features make these nanostructures suitable to reach the low detection limits that are nowadays required for effective clinical and environmental applications, fulfilling in this way the initial expectations of this research project.
Computer simulation of ordering and dynamics in liquid crystals in the bulk and close to the surface
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The aim of this PhD thesis is to investigate the orientational and dynamical properties of liquid crystalline systems, at molecular level and using atomistic computer simulations, to reach a better understanding of material behavior from a microscopic point view. In perspective this should allow to clarify the relation between the micro and macroscopic properties with the objective of predicting or confirming experimental results on these systems. In this context, we developed four different lines of work in the thesis. The first one concerns the orientational order and alignment mechanism of rigid solutes of small dimensions dissolved in a nematic phase formed by the 4-pentyl,4 cyanobiphenyl (5CB) nematic liquid crystal. The orientational distribution of solutes have been obtained with Molecular Dynamics Simulation (MD) and have been compared with experimental data reported in literature. we have also verified the agreement between order parameters and dipolar coupling values measured in NMR experiments. The MD determined effective orientational potentials have been compared with the predictions of MaierSaupe and Surface tensor models. The second line concerns the development of a correct parametrization able to reproduce the phase transition properties of a prototype of the oligothiophene semiconductor family: sexithiophene (T6). T6 forms two crystalline polymorphs largely studied, and possesses liquid crystalline phases still not well characterized, From simulations we detected a phase transition from crystal to liquid crystal at about 580 K, in agreement with available experiments, and in particular we found two LC phases, smectic and nematic. The crystalsmectic transition is associated to a relevant density variation and to strong conformational changes of T6, namely the molecules in the liquid crystal phase easily assume a bent shape, deviating from the planar structure typical of the crystal. The third line explores a new approach for calculating the viscosity in a nematic through a virtual exper- iment resembling the classical falling sphere experiment. The falling sphere is replaced by an hydrogenated silicon nanoparticle of spherical shape suspended in 5CB, and gravity effects are replaced by a constant force applied to the nanoparticle in a selected direction. Once the nanoparticle reaches a constant velocity, the viscosity of the medium can be evaluated using Stokes' law. With this method we successfully reproduced experimental viscosities and viscosity anisotropy for the solvent 5CB. The last line deals with the study of order induction on nematic molecules by an hydrogenated silicon surface. Gaining predicting power for the anchoring behavior of liquid crystals at surfaces will be a very desirable capability, as many properties related to devices depend on molecular organization close to surfaces. Here we studied, by means of atomistic MD simulations, the flat interface between an hydrogenated (001) silicon surface in contact with a sample of 5CB molecules. We found a planar anchoring of the first layers of 5CB where surface interactions are dominating with respect to the mesogen intermolecular interactions. We also analyzed the interface 5CBvacuum, finding a homeotropic orientation of the nematic at this interface.
Intrinsic uncoupling in the ATP synthase of Escherichia coli. Studies on WT and ε-truncated mutants
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The H+/ATP ratio in the catalysis of ATP synthase has generally been considered a fixed parameter. However, Melandri and coworkers have recently shown that, in the ATP synthase of the photosynthetic bacterium Rb.capsulatus, this ratio can significantly decrease during ATP hydrolysis when the concentration of either ADP or Pi is maintained at a low level (Turina et al., 2004). The present work has dealt with the ATP synthase of E.coli, looking for evidence of this phenomenon of intrinsic uncoupling in this organism as well. First of all, we have shown that the DCCD-sensitive ATP hydrolysis activity of E.coli internal membranes was strongly inhibited by ADP and Pi, with a half-maximal effect in the submicromolar range for ADP and at 140 µM for Pi. In contrast to this monotonic inhibition, however, the proton pumping activity of the enzyme, as estimated under the same conditions by the fluorescence quenching of the ÎpH-sensitive probe ACMA, showed a clearly biphasic progression, both for Pi, increasing from 0 up to approximately 200 µM, and for ADP, increasing from 0 up to a few µM. We have interpreted these results as indicating that the occupancy of ADP and Pi binding sites shifts the enzyme from a partially uncoupled state to a fully coupled state, and we expect that the ADP- and Pi-modulated intrinsic uncoupling is likely to be a general feature of prokaryotic ATP synthases. Moreover, the biphasicity of the proton pumping data suggested that two Pi binding sites are involved. In order to verify whether the same behaviour could be observed in the isolated enzyme, we have purified the ATP synthase of E.coli and reconstituted it into liposomes. Similarly as observed in the internal membrane preparation, in the isolated and reconstituted enzyme it was possible to observe inhibition of the hydrolytic activity by ADP and Pi (with half-maximal effects at few µM for ADP and at 400 µM for Pi) with a concomitant stimulation of proton pumping. Both the inhibition of ATP hydrolysis and the stimulation of proton pumping as a function of Pi were lost upon ADP removal by an ADP trap. These data have made it possible to conclude that the results obtained in E.coli internal membranes are not due to the artefactual interference of enzymatic activities other than the ones of the ATP synthase. In addition, data obtained with liposomes have allowed a calibration of the ACMA signal by ÎpH transitions of known extent, leading to a quantitative evaluation of the proton pumping data. Finally, we have focused our efforts on searching for a possible structural candidate involved in the phenomenon of intrinsic uncoupling. The ε-subunit of the ATP-synthase is known as an endogenous inhibitor of the hydrolysis activity of the complex and appears to undergo drastic conformational changes between a non-inhibitory form (down-state) and an inhibitory form (up-state)(Rodgers & Wilce, 2000; Gibbons et al., 2000). In addition, the results of Cipriano & Dunn (2006) indicated that the C-terminal domain of this subunit played an important role in the coupling mechanism of the pump, and those of Capaldi et al. (2001), Suzuki et al. (2003) were consistent with the down-state showing a higher hydrolysis-to-synthesis ratio than the up-state. Therefore, we decided to search for modulation of pumping efficiency in a C-terminally truncated ε mutant. A low copy number expression vector has been built, carrying an extra copy of uncC, with the aim of generating an ε-overexpressing E.coli strain in which normal levels of assembly of the mutated ATP-synthase complex would be promoted. We have then compared the ATP hydrolysis and the proton pumping activity in membranes prepared from these ε-overexpressing E.coli strains, which carried either the WT ε subunit or the ε88-stop truncated form. Both strains yielded well energized membranes. Noticeably, they showed a marked difference in the inhibition of hydrolysis by Pi, this effect being largely lost in the truncated mutant. However, pre-incubation of the mutated enzyme with ADP at low nanomolar concentrations (apparent Kd = 0.7nM) restored the hydrolysis inhibition, together with the modulation of intrinsic uncoupling by Pi, indicating that, contrary to wild-type, during membrane preparation the truncated mutant had lost the ADP bound at this high-affinity site, evidently due to a lower affinity (and/or higher release) for ADP of the mutant relative to wild type. Therefore, one of the effects of the C-terminal domain of ε appears to be to modulate the affinity of at least one of the binding sites for ADP. The lack of this domain does not appear so much to influence the modulability of coupling efficiency, but instead the extent of this modulation. At higher preincubated ADP concentrations (apparent Kd = 117nM), the only observed effects were inhibition of both hydrolysis and synthesis, providing a direct proof that two ADP-binding sites on the enzyme are involved in the inhibition of hydrolysis, of which only the one at higher affinity also modulates the coupling efficiency.
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Die Arbeit beschreibt Untersuchungen zum nichtphoto- chemischen Lochbrennen, das bei 1.4 Kelvin in Form von rein lichtinduzierten Frequenzsprüngen einzelner in p-Terphenyleingebetteter Terrylenmoleküle beobachtet werden kann. Dabei zeigen alle Chromophore aus der X1-Einbaulage ein exzellent reproduzierbares Verhalten, sowohl im bistabilen primären Photozyklus wie auch in dem daran angegliederten sekundärenPhotozyklus, welcher aus drei weiteren spektralen Positionen besteht. Aus den Ergebnissen der nach der genauen Charakterisierung dieser Eigenschaft des Systems durchgeführten Experimente - Fluoreszenzspektroskopie der Photoprodukte, Stark-Effekt-Messungen und Polarisationsmodulation - wird ein Modell für die den lichtinduzierten Änderungen der Absorptionsfrequenzzugrundeliegenden Konformationsänderungender Wirt/Gast- Struktur abgeleitet und diskutiert. Die mittlerweile verfügbaren Ergebnisse von diesbezüglichen molekular- dynamischen Simulationen einer Theoriegruppe ausBordeaux, die alle grundlegenden Annahmen dieses Modellsbestätigen und eine noch genauere mikroskopische Beschreibung des Systems liefern, werden zur Abrundung der Darstellung ebenfalls vorgestellt. Außerdem geht die Dissertation auf die durchgeführten Einzelmolekül- untersuchungen an Terrylen in p-Terphenyl bei Raumtemperatur ein und stellt das im Rahmen der Arbeit aufgebaute temperaturvariable laserscannende Konfokalmikroskop im Detail vor.
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Einfluß der internen Architektur von Polymermikronetzwerken auf Struktur und Dynamik konzentrierter Kolloid-Dispersionen Kugelförmige Polymermikronetzwerk-Kolloide gehören zur Klasse der sogenannten Mikrogele. Dabei handelt es sich um kolloidale Modellsysteme, die durch ihre interne Vernetzungsdichte charakterisiert werden.In dieser Arbeit sollte untersucht werden, ob sich die Wechselwirkungen zwischen den Mikrogel-Kolloiden über ein repulsives Potential der Form U(r) = 1/rn beschreiben lassen und ob der Poten-tialexponent n von der Vernetzungsdichte abhängt. Dazu wurden vor allem die innere Architektur, das Phasenverhalten und der statische Strukturfaktor 1:10, 1:50, 1:72 und 1:100 vernetzter Polymer-Mikronetzwerk-Kolloide bis in den Bereich hochkonzentrierter Dispersionen mit den Mitteln der Kleinwinkelneutronenstreuung, der Digitalphotographie und der statischen Lichtstreuung untersucht. Polymeranalytische Untersuchungen ergaben einen bei der Synthese anfallenden Anteil von unver-netztem, freiem Polymer innerhalb der Mikronetzwerke, welcher sich beim Lösen aus den Netzwerken herausbewegte. Das freie Polymer spielte vor allem beim Phasenverhalten der untersuchten Teilchen eine große Rolle und verursachte bei den Untersuchungen der statischen Strukturfaktoren Abweichun-gen vom 'harte Kugel'-Verhalten. Als Ergebnis der Kleinwinkel-Neutronenstreuung konnte eine ab-nehmende Verteilungsdichte der Vernetzer innerhalb der Polymermikronetzwerke in Richtung der -Teilchenoberfläche nachgewiesen werden. Die damit verbundene Konformationsfreiheit der Polymer-segmente auf der Teilchenoberfläche (bis hin zu 'mushroom'-Strukturen) wurde als Grund dafür an-gesehen, daß sich die Resultate der untersuchten Mikrogele aller Vernetzungsdichten im wesentlichen auf 'harte Kugeln' skalieren lassen.
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Die innerhalb dieser Arbeit mittels moderner Festkörper-NMR-Methoden untersuchte molekulare Dynamik in Poly(methacrylat)-Schmelzen und Polyphenylen-Dendrimeren ist durch eine bemerkenswerte Anisotropie gekennzeichnet.Die Anisotropie der molekularen Dynamik zeigt sich in geschmolzenen, ataktischen und isotaktischen Poly(ethylmethacrylaten) (PEMA) durch die Zeitskalenseparation der segmentellen alpha-Relaxation von einem etwa zwei Größenordnungen langsameren Relaxationsprozeß, welcher die Isotropisierung der Polymerhauptkette wiedergibt. Die Isotropisierungsdynamik der Polymerhauptkette wird - mit Ausnahme von PMMA - durch eine universelle, nicht-korrelationszeitenverteilte Relaxationsmode der Poly(methacrylate) quantifiziert, deren Temperaturabhängigkeit durch einen einheitlichen WLF-Parametersatz beschrieben werden kann. Geometrisch läßt sich die Isotropisierung der Hauptkette durch Sprungprozesse beliebiger Amplitude von Kettenstücken mit gestreckter all-trans-Konformation interpretieren. Die Kette zeigt eine außergewöhnliche konformative Stabilität. WAXS-Messungen deuten für PEMA und seine höheren Homologen die Existenz einer Schichtstruktur an, in der sich die steifen, polaren Hauptketten lokal in Monolagen anordnen, welche durch Bereiche zusammengelagerter Seitengruppen getrennt sind. Die Festkörper-NMR-Untersuchungen an Polyphenylen-Dendrimeren bringen zwei zentrale Aspekte in der wechselseitigen Beziehung von Struktur und Dynamik hervor. Zum einen ist die beobachtete molekulare Dynamik auf lokale Reorientierungen einzelner, terminaler Phenylringe um definierte Achsen beschränkt. Polyphenylen-Dendrimermoleküle sind unter diesen Bewegungen formstabil. Zum anderen können sowohl schnelle, als auch langsame Phenylreorientierungen nachgewiesen werden, wobei jeweils die intramolekulare Packungsdichte der Phenylringe das dynamische Verhalten der Polyphenylen-Dendrimere kontrolliert.
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Das Membranprotein LHCII ist ein Lichtsammelkomplex der höheren Pflanzen, der in vitro, ausgehend von bakteriell überexprimiertem Apoprotein, als Monomer und als Trimer rekonstituiert werden kann. Um Strukturunterschiede zwischen Monomeren und Trimeren zu bestimmen, wurden ortsspezifische Derivatisierungen des Proteins durchgeführt. Dazu wurden verschiedene Mutationen am LHCII vorgenommen. Das einzige Cystein des nativen, maturen LHCII wurde zunächst in ein Serin umgewandelt. Ausgehend von dieser Mutante wurden an fünf Positionen singuläre Cysteine eingefügt. Zugänglichkeitsuntersuchungen mit dem thiolreaktiven Farbstoff Rhodamine Red-Maleimid zeigten zum Teil Unterschiede zwischen Monomeren und Trimeren auf. Außerdem deutete eine zweiphasige Markierungskinetik eines der rekombinanten LHCII auf mindestens zwei konformelle Populationen in Detergenslösung. Die Beobachtungen dieser Arbeit wurden zudem genutzt, um im Strukturmodell des LHCII unklare Positionen näher zu beschreiben. Schließlich wurden einige der LHCII mit angekoppeltem Fluoreszenzfarbstoff spektroskopisch charakterisiert.
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Gegenstand der vorliegenden Arbeit war die Synthese von organischen Photoschalter-Modellen auf der Basis von mesoionischen Pyrimidinium-olaten und Bis(thienylperfluorocyclopentenen), sowie die Darstellung substituierter Biphenyl-Biradikale als Modelle für Ventil-Systeme im Sinne eines neuen Schalter-Ventil-Konzeptes.Aufbauend auf meiner Arbeit über mesoionische Pyrimidinium-olate wurde ein henkelverbrücktes Ansa-Mesoion mit einem 16-gliedrigen Makrocyclus, sowie drei mehrcyclische mesoionische Systeme synthetisiert und auf ihr Schaltverhalten hin untersucht. Das Ansa-Mesoion stellt ein erstes einfaches Modell für Schalter-Ventil-Konjugate dar. Zur Darstellung der photochromen Bis(thienylethene) wurden die aus der Literatur bekannten Syntheserouten nach Irie als auch nach Feringa auf neue Strukturen angewandt und die Schalteigenschaften der Bis(thienylethene) optisch nachgewiesen. Die Anordnung der reaktiven Endgruppen in den synthetisierten Verbindungen schafft ideale Voraussetzungen für eine große konformelle Änderung, welche im Schalter-Ventil-Konjugat erwünscht ist. Durch vielfaches Durchlaufen des Schaltprozesses (> 100 Cyclen) konnte die hohe Reversibilität des Schaltvorganges belegt werden.Als Ventilmodelle wurden mit stabilen Nitroxidradikalen substituierte Biphenyle verwendet, deren primärer konformativer Freiheitsgrad durch die Drehung um die Phenyl-Phenyl-Einfachbindung gegeben ist. Experimentelle ESR-Daten und deren Vergleich mit Spektrensimulationen bestätigten die Abhängigkeit der Austauschwechselwirkung J zwischen den Radikalen vom Biphenyldiederwinkel.
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Die Struktur des Haupt-Lichtsammlerproteins II (LHCIIb) höherer Pflanzen ist aufgrund kristallographischer Strukturanalysen zu 94% aufgeklärt. Dennoch ist es bislang nicht gelungen, die aminoterminale Region des Komplexes vollständig zu lokalisieren. In einem ersten Abschnitt dieser Dissertation sollte anhand einer vergleichenden Bindungsstudie mit Hilfe von in vitro - Rekonstitutionen des LHCIIb geklärt werden, ob es sich bei dem so genannten N - terminalen Trimerisierungsmotiv des Lichtsammlerproteins um eine Interaktionsstelle mit dem Phospholipid Phosphatidylglyzerin handelt. Dazu wurden mehrere vergleichende Lipidbindungsstudien an rekombinantem Wildtyp - Protein und verschiedenen LHCIIb - Trimerisierungsmotiv - Mutanten durchgeführt, die allerdings nicht zu reproduzierbaren Ergebnissen führten.Im zweiten Teil dieser Arbeit wurden intra- und intermolekulare Distanzmessungen an rekombinantem LHCIIb mit Hilfe der Elektronenspin - Resonanz - Spektroskopie durchgeführt. Dazu wurden zweifach mit einem Spin - Label markierte LHCIIb - Monomere und Trimere mit je einer Markierungsposition pro Monomer benutzt. Im Anschluss an die Messungen wurden die erhaltenen Distanzinformationen zusammen mit den bereits zugänglichen Kristallstrukturdaten des Komplexes für eine Modellierung der aminoterminalen Region des LHCIIb verwendet. Die resultierenden Modelle lassen den Schluss zu, dass es im LHCIIb - Trimer zu konformativen Restriktionen des Aminoterminus kommt. Dem entgegen findet man eine größere konformative Diversität in den vermessenen monomeren Komplexen.
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Über die Sekundärstruktur von LI-Cadherin ist bislang wenig bekannt. Es gibt keine Röntgenanalysen und keine NMR-spektroskopische Untersuchungen. Man kann nur aufgrund der Sequenzhomologien zu den bereits untersuchten klassischen Cadherinen vermuten, daß im LI-Cadherin ähnliche Verhältnisse in der entscheidenden Wechselwirkungsdomäne vorliegen. In Analogie zum E-Cadherin wurde angenommen, daß es im LI-Cadherin eine „homophile Erkennungsregion“ gibt, die in einer typischen beta-Turn-Struktur mit anschließenden Faltblattbereichen vorliegen sollte. Um den Einfluß verschiedener Saccharid-Antigene auf die Turn-Bildung zu untersuchen, wurden im ersten Teil der vorliegenden Arbeit verschiedene Saccharid-Antigen-Bausteine synthetisiert, mit denen dann im zweiten Teil der Arbeit durch sequentielle Festphasensynthese entsprechende Glycopeptidstrukturen aus dieser Region des LI-Cadherins aufgebaut wurden. Zur Synthese sämtlicher Antigen-Bausteine ging man von D-Galactose aus, die über das Galactal und eine Azidonitratisierung in vier Stufen zum Azidobromid umgesetzt wurde. In einer Koenigs-Knorr-Glycosylierung wurde dieses dann auf die Seitenkette eines geschützten Serin-Derivats übertragen. Reduktion und Schutzgruppenmanipulationen lieferten den TN Antigen-Baustein. Ein TN-Antigen-Derivat war Ausgangspunkt für die Synthesen der weiteren Glycosyl-Serin-Bausteine. So ließ sich mittels der Helferich-Glycosylierung der T Antigen-Baustein herstellen, und der STN-Antigen-Baustein wurde durch eine Sialylierungsreaktion und weitere Schutzgruppenmanipulationen erhalten. Da die Route über das T-Antigen-Derivat den Hauptsyntheseweg für die weiteren komplexeren Antigene bildete, wurden verschiedene Schutzgruppenmuster getestet. Darauf aufbauend ließen sich durch verschiede Glycosylierungsreaktionen und Schutzgruppenmanipulationen der komplexe (2->6)-ST-Antigen-Baustein, (2->3)-Sialyl-T- und Glycophorin-Antigen-Baustein synthetisieren. Im nächsten Abschnitt der Doktorarbeit wurden die synthetisierten Saccharid-Antigen-Serin-Konjugate in Festphasen-Glycopeptidsynthesen eingesetzt. Zunächst wurde ein mit dem TN Antigen glycosyliertes Tricosapeptid hergestellt. Mittels NMR-spektroskopischen Untersuchungen und folgenden Energieminimierungsberechnungen konnte eine dreidimensionale Struktur ermittelt werden. Die Peptidsequenz des Turn-bildenden Bereichs wurde für die folgenden Synthesen gewählt. Die Abfolge der einzelnen Reaktionsschritte für die Festphasensynthesen mit den verschiedenen Saccharid-Antigen-Bausteinen war ähnlich. Insgesamt verlief die Festphasen-Glycopeptidsynthese in starker Abhängigkeit vom sterischen Anspruch der Saccharid-Bausteine. Sämtliche so synthetisierten Glycopeptide wurden NMR spektroskopisch charakterisiert und mittels NOE-Experimenten hinsichtlich ihrer Konformation untersucht. Durch diese Bestimmung der räumlichen Protonen-Protonen-Kontakte konnte mittels Rechnungen zur Energieminimierung, basierend auf MM2 Kraftfeldern, eine dreidimensionale Struktur für die Glycopeptide postuliert werden. Sämtliche synthetisierten Glycopeptide weisen eine schleifenartige Konformation auf. Der Einfluß der Saccharid-Antigene ist unterschiedlich, und läßt sich in drei Gruppen einteilen.
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The research has included the efforts in designing, assembling and structurally and functionally characterizing supramolecular biofunctional architectures for optical biosensing applications. In the first part of the study, a class of interfaces based on the biotin-NeutrAvidin binding matrix for the quantitative control of enzyme surface coverage and activity was developed. Genetically modified ß-lactamase was chosen as a model enzyme and attached to five different types of NeutrAvidin-functionalized chip surfaces through a biotinylated spacer. All matrices are suitable for achieving a controlled enzyme surface density. Data obtained by SPR are in excellent agreement with those derived from optical waveguide measurements. Among the various protein-binding strategies investigated in this study, it was found that stiffness and order between alkanethiol-based SAMs and PEGylated surfaces are very important. Matrix D based on a Nb2O5 coating showed a satisfactory regeneration possibility. The surface-immobilized enzymes were found to be stable and sufficiently active enough for a catalytic activity assay. Many factors, such as the steric crowding effect of surface-attached enzymes, the electrostatic interaction between the negatively charged substrate (Nitrocefin) and the polycationic PLL-g-PEG/PEG-Biotin polymer, mass transport effect, and enzyme orientation, are shown to influence the kinetic parameters of catalytic analysis. Furthermore, a home-built Surface Plasmon Resonance Spectrometer of SPR and a commercial miniature Fiber Optic Absorbance Spectrometer (FOAS), served as a combination set-up for affinity and catalytic biosensor, respectively. The parallel measurements offer the opportunity of on-line activity detection of surface attached enzymes. The immobilized enzyme does not have to be in contact with the catalytic biosensor. The SPR chip can easily be cleaned and used for recycling. Additionally, with regard to the application of FOAS, the integrated SPR technique allows for the quantitative control of the surface density of the enzyme, which is highly relevant for the enzymatic activity. Finally, the miniaturized portable FOAS devices can easily be combined as an add-on device with many other in situ interfacial detection techniques, such as optical waveguide lightmode spectroscopy (OWLS), the quartz crystal microbalance (QCM) measurements, or impedance spectroscopy (IS). Surface plasmon field-enhanced fluorescence spectroscopy (SPFS) allows for an absolute determination of intrinsic rate constants describing the true parameters that control interfacial hybridization. Thus it also allows for a study of the difference of the surface coupling influences between OMCVD gold particles and planar metal films presented in the second part. The multilayer growth process was found to proceed similarly to the way it occurs on planar metal substrates. In contrast to planar bulk metal surfaces, metal colloids exhibit a narrow UV-vis absorption band. This absorption band is observed if the incident photon frequency is resonant with the collective oscillation of the conduction electrons and is known as the localized surface plasmon resonance (LSPR). LSPR excitation results in extremely large molar extinction coefficients, which are due to a combination of both absorption and scattering. When considering metal-enhanced fluorescence we expect the absorption to cause quenching and the scattering to cause enhancement. Our further study will focus on the developing of a detection platform with larger gold particles, which will display a dominant scattering component and enhance the fluorescence signal. Furthermore, the results of sequence-specific detection of DNA hybridization based on OMCVD gold particles provide an excellent application potential for this kind of cheap, simple, and mild preparation protocol applied in this gold fabrication method. In the final chapter, SPFS was used for the in-depth characterizations of the conformational changes of commercial carboxymethyl dextran (CMD) substrate induced by pH and ionic strength variations were studied using surface plasmon resonance spectroscopy. The pH response of CMD is due to the changes in the electrostatics of the system between its protonated and deprotonated forms, while the ionic strength response is attributed from the charge screening effect of the cations that shield the charge of the carboxyl groups and prevent an efficient electrostatic repulsion. Additional studies were performed using SPFS with the aim of fluorophore labeling the carboxymethyl groups. CMD matrices showed typical pH and ionic strength responses, such as high pH and low ionic strength swelling. Furthermore, the effects of the surface charge and the crosslink density of the CMD matrix on the extent of stimuli responses were investigated. The swelling/collapse ratio decreased with decreasing surface concentration of the carboxyl groups and increasing crosslink density. The study of the CMD responses to external and internal variables will provide valuable background information for practical applications.
