Browsing by Author "Naidoo, Venthan B."
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- ItemThe supramolecular chemistry of novel synthetic biomacromolecular assemblies(Stellenbosch : Stellenbosch University, 2004-04) Naidoo, Venthan B.; Sanderson, R. D.; Rautenbach, Marina; Stellenbosch University. Faculty of Science. Dept. of Chemistry and Polymer Sciences.ENGLISH ABSTRACT: Over the past decade peptide bola-amphiphiles have been the subject of much attention because of their role as potential models of functionalised membranes and as new generation surfactants. In the quest for new surfactants a peptidomimetic-based approach was used to design a library of novel 'hybrid' bola-amphiphilic peptide surfactants derived from sapecin B and a model symmetrical oligo-glycine bola-amphiphile. The library was divided into different series, each one purpose-built; first, to investigate hierarchal supramolecular architecture and, second, to investigate potential antimicrobial activity. The bola-amphiphiles were synthesised using Fmoc-polyamide based solid phase peptide synthesis and purified via high performance liquid chromatography. The peptide hybrids were characterised using electro spray mass spectrometry, nuclear magnetic resonance, different modes of electron microscopy, Fourier-transform infrared spectroscopy and, in some cases, further studies were done using circular dichroism and bioactivity tests. The model bola-amphiphile suberamide(GGh was synthesised using peptide fragment condensation based on solid phase peptide synthesis. The synthesis is bi-directional (N~C and C~N) and versatile, making it possible to synthesis new dicarboxylic oligopeptide bola-amphiphiles and other analogous compounds. The product, suberarnide(GG)2, was purified using its inherent ability to self-assemble in an acidic solution. Novel asymmetrical bola-amphiphiles composed of dipeptide head groups linked via an aliphatic (I)-amino acid, serving as a hydrocarbon spacer, were also synthesized. Two small libraries of bola-amphiphiles were established - the first involved variation in to-amino acid length and the other variation in the C-terminal amino acid. The bolaamphiphiles were self-assembled in either 0.1% trif1uoroacetic acid or 0.1% triethylamine. Electron microscopy revealed the formation of a variety of higher order supramolecular architectures based on ~-sheet self-assembly. FT-IR spectrometry indicated that interlayer and intralayer hydrogen bond networks, together with strong selfassociation, promoted by the hydrophobic effect and, in certain instances, electrostatic interactions, are responsible for the variety of supramolecular architectures. Variations in the higher order structures can be attributed to amino acid composition, specifically length of m-amino acid, nature of the C-terminal amino acid and the optimised solvent conditions used for the self-assembly process. A third library of novel 'hybrid' bola-amphiphilic peptide surfactants, in which a cationic tripeptide motif from antimicrobial peptides was combined in a hybrid molecule containing a oi-amino acid residue, was established. These bola-amphiphiles displayed potent antimicrobial activity against both Gram-positive and Gram-negative bacteria; the analogues were as active or more active than the leader peptides yet, remarkably, displayed little or no appreciable haemolytic activity. These organopeptide bolaamphiphiles thus demonstrated selective toxicity towards bacteria. The hydrophobicity imparted by the co-amino acid has contrasting effects on haemolysis and antimicrobial activity of the peptide analogues. The other unique feature of these peptides and their analogues is the fact they self-assembled into complex supramolecular architectures, composed primarily of ~-sheets. Their self-assembly is primarily governed by hydrophobic interactions together with inter and intralayer hydrogen bonding. Electron microscopy clearly revealed higher order structures for both peptides and analogues. The generation of higher order supramolecular architecture is dependent on optimisation of ~- sheet self-assembly whereas antimicrobial activity is dependent on the balance between net positive charge and optimum hydrophobicity of the peptide hybrids. This study has demonstrated that it is possible to design hybrid peptide surfactants capable of producing higher order supramolecular architecture and improving the antimicrobial activity whilst reducing the haemolytic effect. The study and design of these versatile 'purpose-built' bio-inspired surfactants heralds a novel approach, one that shows tremendous potential.