Refine
Has Fulltext
- yes (3)
Is part of the Bibliography
- yes (3)
Document Type
- Doctoral Thesis (3)
Language
- English (3) (remove)
Keywords
- non-covalent interactions (3) (remove)
Institute
- Institut für Organische Chemie (3) (remove)
The effective binding of anions like carboxylates and phosphates in aqueous solutions is of particular interest for various reasons. The natural archetypes of effective anion receptors are enzymes that contain often arginine as relevant amino acid in the binding pocket. For this reason, one class of artificial anion receptors that emerged more than two decades ago mimics the anion binding with the guanidinium group present in the amino acid side chain. In 1999, Schmuck and coworkers developed a new class of guanidinium-based oxo anion receptor that binds carboxylates even in aqueous media. The binding modes of the 2-(guanidiniocarbonyl)-1H-pyrroles are based on individually weak non-covalent interaction between artificial host and substrate like ion pairing and multiple hydrogen bonds. The zwitterionic derivative with substitution of a carboxylate group in position 5 of the pyrrole ring system shows a strong self-assembly to discrete dimers (dimer 1) with an estimated association constant of 170 M-1 even in water. In order to further improve the structure motif for an effective oxo anion binding it is therefore of great interest to quantify the different intermolecular interactions between two monomeric units of 1. Against this background several theoretical ab initio studies were conducted in order to elucidate the influences of intrinsic properties as well as solvent effects on the stability of self-assembled dimers. In chapter 4.1 the molecular interactions in dimer 1 were investigated by comparison to various “knock-out” analogues. In these analogues single hydrogen bonds were switched off by substitution of hydrogen donor atoms with either methylene groups or ether bridges. The calculations were done for vacuum and solvation, as represented by a conductor-like polarizable continuum. It could be shown that the application of a simple continuum solvent model fails to predict the absolute energies of the knock-out analogues in strongly polar solvents. However, the calculated trends can explain the relative stabilities. In chapter 4.2 the structural similarity of arginine with structure 1 was used in order to examine the dependence of self-assembly from the flexibility of the molecular structure. In chapter 4.2.1 new global minimum structures of the canonical and zwitterionic arginine in gas phase were found by means of exhaustive force field based conformational searches in conjunction with ab initio structure optimizations of the lowest energy conformers. Most of the newly identified minimum conformers of both the zwitterionic and canonical tautomer revealed geometrical arrangements with hitherto unreported stacked orientations of the terminal groups. Finally a novel global minimum structure was detected that is more than 8 kJ mol-1 lower in energy than the previously published conformers. The same strategy for finding minimum energy conformers of the arginine monomer has also been employed for the arginine dimer structures. While previous theoretical studies favoured directed hydrogen bonds the new global minimum structure MMFF1 is about 60 kJ mol-1 more stable and exhibits a stacked orientation of the guanidinium and carboxylate groups. The importance of rigidity on the dimer stability was proven by calculations of an artificially stiffened arginine dimer system. The high binding affinity dimer 1 results by about 50% from the rigidity of the monomers which prevents any intramolecular stabilization. In chapter 4.3 novel structure motifs with varying ring systems have been examined on a DFT level of theory in order to make proposals for an improved carboxylate binding motif. The direct dependency of the dimerization energy on an increasing dipole moment was demonstrated by various anellated ring structures. The influence of the delocalization in the monomer on the dimerization energy was examined by variation of the electronic structure of electronically decoupled biphenylenes. With the aid of various substituted 7-guanidinioindole-2-carboxylate derivatives we could show that the carbonyl function is mainly responsible for the advantageous preorganisation, whereas the effect on the acidity seems to be only of minor importance. In the last chapter cooperativity effects in supramolecular assemblies have been investigated. This was achieved by NMR shift calculations of adenosine-carboxylic acid complexes as model systems and comparison to experimental low-temperature NMR studies. We could demonstrate that only by applying vibrational averaged NMR shifts the experimental proton shifts obtained at very low temperatures in the hydrogen bond exchange regime could be reproduced.
The main focus of this thesis was the synthesis and analysis of multifunctional oligopeptides. The study of their non-covalent interactions with various counterparts revealed interesting new results, leading to both methodological and application related progress. The first project of this thesis concentrated on the in-depth analysis of the peptide receptor CBS-Lys-Lys-Phe-NH2 to acquire a better understanding of its binding mode upon complexation with a substrate. In this context it was possible to develop—in cooperation with the group of Prof. Sebastian Schlücker—a direct and label free spectroscopic detection of immobilized compounds which are often found in combinatorial libraries. This new screening method utilizes the advantages of the surface enhanced Raman spectroscopy and allowed for the first time a surface mapping of a single polystyrene bead for the identification of peptides in femtomolar concentrations. Hence, this method allows a very fast and sensitive detection of resin bound compounds. The development of this promising new approach set the starting point for future experiments to enable on-bead library screenings and to investigate the complex formation of immobilized compounds. After the comprehensive analysis of the basic structural features of small peptide receptors in the first part of this thesis, the second big block focused on its in vitro evaluation using biological relevant targets. Therefore, several different modifications of the initial peptide structures were synthesized. These modifications provided a molecular toolkit for the tailor made synthesis of structures individually designed for the respective target. The first tests addressed the interaction with Alzheimer’s related amyloid fibrils. During these experiments, the successful SPPS syntheses of tri- and tetravalent systems were achieved. The comparison of the multivalent form with the corresponding monovalent version was then under special investigations. These concentrated mainly on the interaction with various bacteria strains, as well as with different parasites. To localize the compounds within the organisms, the synthesis of fluorescence labelled versions was achieved. In addition, several compounds were tested by the Institute for Molecular Infection Biology of the University of Würzburg for their antibacterial activity. This thorough evaluation of the biological activity generated precious information about the influence of small structural changes in the peptide receptors. Especially the distinct influence of the multivalency effect and the acquired synthetic skills led to the development of an advanced non-covalent recognition event, as described in the final project of this thesis. The last part of this thesis discussed the development of a novel inhibitor for the serine protease beta-tryptase based on a tailor-made surface recognition event. It was possible to study and analyze the complex interaction with the unique structure of tryptase, that features a tetrameric frame and four catalytic cleavage sites buried deep inside of the hollow structure. However, the point of attack were not the four binding pockets, as mostly described in the literature, but rather the acidic areas around the cleavage sites and at the two circular openings. These should attract peptides with basic residues, which then can block the accessibility to the active sites. A combinatorial library of 216 tetravalent peptide compounds was synthesized to find the best structural composition for the non-covalent inhibition of beta-tryptase. For the screening of the library a new on-bead assay was applied. With this method a simultaneous readout of the total inhibition of all library members was possible, thus allowing a fast and direct investigation of the still resin bound inhibitors. Several additional experiments in solution unveiled the kinetics of the inhibition process. In conclusion, both mono- and multivalent inhibitors interact in a non-destructive and reversible way with the tryptase.
The presented work in the field of supramolecular chemistry describes the synthesis and detailed investigation of (bi)pyridine-based oligo(phenylene ethynylene) (OPE) amphiphiles, decorated with terminal glycol chains. The metal-ligating property of these molecules could be exploited to coordinate to Pd(II) and Pt(II) metal ions, respectively, resulting in the creation of novel metallosupramolecular π-amphiphiles of square-planar geometry.
The focus of the presented studies is on the self-assembly behaviour of the OPE ligands and their corresponding metal complexes in polar and aqueous environment. In this way, the underlying aggregation mechanism (isodesmic or cooperative) is revealed and the influence of various factors on the self-assembly process in supramolecular systems is elucidated. In this regard, the effect of the molecular design of the ligand, the coordination to a metal centre as well as the surrounding medium, the pH value and temperature is investigated.