1.The Applications of Glutarimides in Mappicine Ketone Synthesis 2. Formal Synthesis of Udoteatrial

Lin, Ching-Han

25 May 2003

1. We have successfully developed an efficient approach to 3,4-disubstituted pyridin-2-ones from Glutarimide, and proved to be applicable for the synthesis of mappicine ketone 2. Synthesis of tricyclic lactonedemonstrate the utility Norrish type 1 reaction for the formal synthesis of udotartrial

pyridinone

photocleavage

Synthetic Studies toward Onychine and Cleistopholine

Chang, Sheng-pei

06 July 2004

We have explored a formal [3+3] strategy that is synthetically useful for constructing a glutarimide in one step.Then we studied the synthesis of Onychine and Cleistopholine by means of the glutarimide.

pyridine

onychine

azaanthraquinone

pyridinone

cleistopholine

azafluorenone

Analyse et modélisation de nouveaux inhibiteurs non nucléosidiques de la transcriptase inverse du virus de l'immunodéficience humaine de type 1 (VIH-1).

Boland, Sandro

27 February 2004

Résumé Le virus de l’immunodéficience humaine (VIH) est l’agent pathogène responsable du Syndrome del’Immunodéficience Acquise (SIDA). A l’heure actuelle, le traitement des patients infectés par le VIH estbasé sur l’emploi de substances chimiques destinées à perturber les différentes étapes du cycle deréplication du virus (chimiothérapie). Même si elles permettent d’améliorer l’état de santé des patientset d’augmenter leur espérance de vie, ces thérapies restent coûteuses, contraignantes et imparfaites.La recherche de nouveaux composés plus efficaces reste donc d’actualité. Ce travail de thèse est dédié à la conception rationnelle et à l’étude d’inhibiteurs non nucléosidiques dela transcriptase inverse du VIH-1 (INNTI) une enzyme essentielle au cycle de réplication de ce virus.Les molécules étudiées dérivent du cycle 2-pyridinone dont sont déjà issues plusieurs familles d’INNTIdécrites dans la littérature. La conception rationnelle de molécules d’intérêt pharmaceutique nécessite une bonne compréhensiondes interactions mises en jeu entre la macromolécule cible et ses ligands. Etant donné qu’aucunestructure cristallographique d’un complexe TI-pyridinone n’est disponible dans la littérature, la premièrepartie de ce travail est consacrée à la proposition d’un mode d’interaction TI-pyridnone et à larationalisation des relations structure-activité liées à cette famille de molécules. Les informationsrecueillies lors de cette étude théorique sont ensuite exploitées dans le but d’aider au développementd’une nouvelle série d’inhibiteurs. Abstract Human Immunodeficiency Virus (HIV) is the causative agent of Acquired Immune DeficiencySyndrome (AIDS). Treatment of HIV-infected patients is currently based on the use of chemicalcompounds that interfere with various steps of the viral replication cycle (chemotherapy).Although these therapies allow for a significant improvement of a patient’s health, theynonetheless remain imperfect and expensive. Research for new and improved anti-HIVcompounds is therefore necessary. This Ph. D. thesis is dedicated to the rational design and analysis of new non nucleosideinhibirors of HIV-1 reverse transcriptase (NNRTI), a key enzyme in HIV lifecycle. Most of thestudied compounds are derived from the 2-pyridinone ring, that is part of several NNRTIfamilies. Rational drug design usually requires a good understanding of the main interactions betweenthe macromolecular target (RT) and its ligands. However, no crystal structure of a RT-pyridinone complex has been reported yet. Our first objective was therefore to build atheoretical model describing RT-pyridinone interactions and providing a better understanding ofstructure-activity relationships among pyridinones. The information obtained in this theoreticalmodel was then used in order to develop new and potent inhibitors.

INNTI

non nucléoside

pyridinone

modélisation moléculaire

conception rationelle

pharmacophore

HIV-1

antivirals

reverse transcriptase

inhibitor

non-nucleoside

rational drug design

molecular modeling

pharmacophore

inhibiteur

transcriptase inverse

antiviraux

VIH-1

pyridinone

Synthesis, biophysical analysis and biological evaluation of tricyclic pyrones and pyridinones as anti-alzheimer agents

Rana, Sandeep

January 1900

Doctor of Philosophy / Department of Chemistry / Duy H. Hua / The objectives of this research project were to (i) synthesize different bicyclic and tricyclic pyrone and pyridinone compounds; (ii) study the mechanism of action of these compounds in solution as anti-Aβ (amyloid β) agents using different biophysical techniques; and (iii) study the biological activity of pyrone compounds for the counteraction of Aβ toxicity using MC65 cells, a human neuroblastoma cell line and 5X- familial Alzheimer’s disease (5X FAD, a transgenic mice with five different mutations) mice. A series of tricyclic pyrone and pyridinone compounds were investigated. The tricyclic pyrones and pyridinones were synthesized utilizing a condensation reaction between cyclohexenecarboxaldehye (25) and 4-hydroxy-6-methyl-2-pyone (24) or 4-hydroxy-6-methyl-2-pyridinone (51), respectively. A tricylic pyrone molecule CP2 (2, code name) was synthesized and has an adenine base unit attached to the pyrone core. For structure activity relationship (SAR) studies, the adenine group of CP2 was replaced with other DNA base units (thymine, cytosine and guanine) and various heterocyclic moieties. Since nitrogen containing compounds often exhibit increased bioactivity and brain-penetrating abilities, oxygen atom (O5’) was displaced with a nitrogen atom in the middle ring of the tricyclic pyrone. A condensation reaction of pyrone 51 and 25 was carried out to give the linear pyranoquinoline (52) and the L-shaped pyranoisoquinoline (53). The neurotoxicity of amyloid-β protein (Aβ) is widely regarded as one of the fundamental causes of neurodegeneration in Alzheimer’s disease (AD). Recent studies suggest that soluble Aβ oligomers rather then protofibrils and fibrils may be the primary toxic species. Different biophysical techniques including atomic force microscopy (AFM), circular dichroism (CD), surface plasmon resonance (SPR) spectroscopy, and protein quantification assays were used to study the mechanism of aggregation of Alzheimer Aβ peptide in solution. In search of potentially bioactive compounds for AD therapies, MC65 cell line was used as a screening model. Different tricyclic pyrone and pyridinone compounds protect MC65 cells from death. We studied the efficacy of CP2 in vivo by treatment of 5X FAD mice, a robust Aβ42-producing animal model of AD, with a 2-week course of CP2, which resulted in 40% and 50% decreases in non-fibrillar and fibrillar Aβ species respectively.

Anti-Alzheimer agents

Tricyclic pyrone

Tricyclic pyridinone

Atomic force microscopy

MC65 cells

In vivo studies

Chemistry, Biochemistry (0487)

Chemistry, Organic (0490)

Chemistry, Pharmaceutical (0491)

Synthesis and biological evaluation of Bicyclic β-Lactams and 2-Pyridinones : Pilicides Targeting Pilus Biogenesis in Pathogenic Bacteria

Emtenäs, Hans

January 2003

New methods have been developed for the synthesis of bicyclic β-lactams and 2-pyridinones by combining acyl Meldrum’s acids and Δ2-thiazolines. The 2-pyridinones were synthesised both in solution using conventional heating or microwave assisted heating as well as by solid supported chemistry. The compounds (pilicides) were designed to interfere with the assembly of pili in uropathogenic E. coli by inhibiting the periplasmic chaperones. The affinity of the pilicides to the chaperones was investigated with surface plasmon resonance technique (Biacore) and with relaxation-edited 1H NMR spectroscopy experiments. Finally, the pilicides were investigated for their ability to inhibit pili formation in uropathogenic E. coli in a hemagglutination assay, where members of the 2-pyridinone family proved to be able to cause depiliation.

Organic chemistry

β-lactam

2-pyridinone

2-pyridone

Meldrum’s acid

Δ2-thiazoline

solid-phase synthesis

microwave assisted synthesis

antibacterial

pili

pilicide

Organisk kemi

Organic chemistry

Organisk kemi