Browsing by Author "Leussa, Nyango-Nkeh Adrienne"
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- ItemCharacterisation of small cyclic peptides with antilisterial and antimalarial activity(Stellenbosch : Stellenbosch University, 2014-04) Leussa, Nyango-Nkeh Adrienne; Rautenbach, Marina; Stellenbosch University. Faculty of Science. Dept. of Biochemistry.ENGLISH ABSTRACT: Antimicrobial peptides (AMPs) are currently the most researched group of compounds for new antimicrobial drugs especially with the rise in resistance to almost all available drugs by public health relevant pathogens. In this study we set out to characterise small cyclic AMPs in terms of their activity towards human pathogens Listeria monocytogenes, a food-borne pathogen causing listeriosis and Plasmodium falciparum, a parasite that causes malaria respectively, each a threat to public health. One of the small cyclic peptide libraries examined is the tyrocidines (Trcs) and analogues, which are cyclic decapeptides [cyclo-(D-Phe-Pro-(Phe/Trp)-D-Phe/DTrp)-Asn-Gln-(Tyr/Phe/Trp)-Val- (Orn/Lys)-Leu] produced by the Gram-positive bacteria Bacillus aneurinolyticus as part of the tyrothricin complex which is non-ribosomally synthesised during sporulation. Previous research found that the six major Trcs were active against Listeria monocytogenes and Plasmodium falciparum and it was found that the identity of the aromatic residues in the aromatic dipeptide unit has an important role in activity. We set out to extend the qualitative structure to activity relationship (QSAR) studies using more Trc analogues and small synthetic Arg- and Trp-rich cyclic peptides (RW-peptides) in a bid to establish essential structural motifs and pre-requisites for activity. Eight natural and three synthetic Trc analogues and fifteen RW-peptides were either naturally or by chemical synthesis produced and characterised in terms of chemical character and biological activity. The Trcs were significantly more active than RW peptides, although much more haemolytic and thus toxic. Results indicated the relevance for hydrogen bonding with an aromatic amino acid residue for selective activity towards the leucocin A resistant L. monocytogenes B73-MR1. However, structural properties favouring a tighter membrane interaction hindered the Trc mode of action (MOA). We determined that Gln6 and hydroxyl group of Tyr7 may be involved in interaction with the putative target in L. monocytogenes. There was also need for an amphipathic balance between hydrophobicity and size/steric parameters for optimal activity. From our QSAR studies we predict as lead peptide for a future library of antilisterial Trcs: cyclo(VOMe3LfPWfNQY). Furthermore, the antilisterial activity of the Trcs was found to be predominantly lytic and salt tolerant while RW-peptides were non-lytic and sensitive to Ca2+. We confirmed that Ca2+ enhanced Trc antilisterial activity with Ca2+ increasing the Trc anti-metabolic activity, but conversely inducing a non-lytic mechanism of action. From model membrane studies, we propose that the calcium induced Trc non-lytic MOA could be due to detrimental lipid demixing, presence of a Trc sensitive Ca2+-induced non-membrane target in the prematurely calcium induced intracellular anaerobic form of Listeria monocytogenes, and/or the Trc-Ca2+ complexes may inhibit key components such as membrane bound electron transport system or bacterial dehydrogenases. We confirmed, as previously found, that the Trcs have potent antimalarial activity that is sequence specific and non-lytic. The RW-peptides had very weak activity, but our results again indicated that more hydrophobic and haemolytic peptides tend to be more active, particularly the RW-peptide containing the Trp analogue β-(benzothien-3-yl)-alanine (Bal). A novel finding was that one of the more polar Trc C analogues, namely tryptocidine C (Tpc C), in contrast to Trc C showed potent antimalarial activity indicating the specific sequence and the role of the Trp7 in activity. From these results a proposed lead peptide for future research is cyclo[VOLfP(Bal)fNQ(Bal)]. Furthermore, in our search for the Trc and Tpc C target(s) we employed high resolution fluorescence microscopy. Results show that Trc led to disorganisation of neutral lipid structures and chromatin halting growth in late trophozoite/early schizont stages. This indicated that membrane structures containing neutral lipids, as well as chromatin may be targeted by the Trcs. Another novel finding in our studies was that chloroquine (CQ) resistance not only correlated with resistance to Trcs, but the Trcs and CQ were found to be antagonistic towards each other’s activity. This indicated a shared target and we propose the food vacuole as another of the Trc targets in P. falciparum.