Development of 2-Pyridone-based central fragments : Affecting the aggregation of amyloid proteins

Sellstedt, Magnus

January 2012

There are many applications of small organic compounds, e.g. as drugs or as tools to study biological systems. Once a compound with interesting biological activity has been found, medicinal chemists typically synthesize small libraries of compounds with systematic differences to the initial “hit” compound. By screening the new ensemble of compounds for their ability to perturb the biological system, insights about the system can be gained. In the work presented here, various ways to synthesize small libraries of ring-fused 2‑pyridones have been developed. Members of this class of peptidomimetic compounds have previously been found to have a variety of biological activities, e.g. as antibacterial agents targeting virulence, and as inhibitors of the aggregation of Alzheimer b‑peptides. The focus in this work has been to alter the core skeleton, the central fragment, of the previously discovered biologically active 2‑pyridones and evaluate the biological effects of these changes. Several new classes of compounds have been constructed and their preparations have included the development of multi-component reactions and a method inspired by diversity-oriented synthesis. Some of the new compounds have been evaluated for their effect on the fibrillation of different amyloid proteins. Both the Parkinson-associated amyloid protein a-synuclein and the bacterial protein CsgA that is involved in bacterial biofilm formation are affected by subtle changes of the compounds’ central fragments. This is an example of the usefulness of central-fragment alterations as a strategy to probe structure-activity relationships, and the derived compounds may be used as tools in further study of the aggregation of amyloid proteins.

2-pyridone

central fragment alteration

multi-component reactions

directed diversity-oriented synthesis

peptidomimetics

amyloid

protein aggregation

pilicide

curlicide

Pilicides and Curlicides : Design, synthesis, and evaluation of novel antibacterial agents targeting bacterial virulence

Chorell, Erik

January 2010

New strategies are needed to counter the growing problem of bacterial resistance to antibiotics. One such strategy is to design compounds that target bacterial virulence, which could work separately or in concert with conventional bacteriostatic or bactericidal antibiotics. Pilicides are a class of compounds based on a ring-fused 2-pyridone scaffold that target bacterial virulence by blocking the chaperone/usher pathway in E. coli and thereby inhibit the assembly of pili. This thesis describes the design, synthesis, and biological evaluation of compounds based on the pilicide scaffold with the goal of improving the pilicides and expanding their utility. Synthetic pathways have been developed to enable the introduction of substituents at the C-2 position of the pilicide scaffold. Biological evaluation of these compounds demonstrated that some C-2 substituents give rise to significant increases in potency. X-ray crystallography was used to elucidate the structural basis of this improved biological activity. Furthermore, improved methods for the preparation of oxygen-analogues and C-7 substituted derivatives of the pilicide scaffold have been developed. These new methods were used in combination with existing strategies to decorate the pilicide scaffold as part of a multivariate design approach to improve the pilicides and generate structure activity relationships (SARs). Fluorescent pilicides were prepared using a strategy where selected substituents were replaced with fluorophores having similar physicochemical properties as the original substituents. Many of the synthesized fluorescent compounds displayed potent pilicide activities and can thus be used to study the complex interactions between pilicide and bacteria. For example, when E. coli was treated with fluorescent pilicides, it was found that the compounds were not uniformly distributed throughout the bacterial population, suggesting that the compounds are primarily associated to bacteria with specific properties. Finally, by studying compounds designed to inhibit the aggregation of Aβ, it was found that some compounds based on the pilicide scaffold inhibit the formation of the functional bacterial amyloid fibers known as curli; these compounds are referred to as 'curlicides'. Some of the curlicides also prevent the formation of pili and thus exhibit dual pilicide-curlicide activity. The potential utility of such 'dual-action' compounds was highlighted by a study of one of the more potent dual pilicide-curlicides in a murine UTI model were the compound was found to significantly attenuate virulence in vivo.

pilicide

curlicide

anti-virulence

chaperone/usher pathway

antibacterial

pili

curli

Escherichia coli

biofilm inhibitor

2-pyridone

peptidomimetic

Organic chemistry

Organisk kemi

Bioorganic chemistry

Bioorganisk kemi

Pharmaceutical chemistry

Läkemedelskemi

Organic synthesis

Organisk syntes

Infectious diseases

Infektionssjukdomar