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Chemoproteomic Profiling of a Pharmacophore-Focused Chemical Library / ファーマコフォアに焦点を当てたケミカルライブラリーのケモプロテオミクスプロファイリングPUNZALAN, LOUVY LYNN CALVELO 23 September 2020 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22733号 / 医博第4651号 / 新制||医||1046(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 萩原 正敏, 教授 岩田 想, 教授 渡邊 直樹 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Antimalarial Agents: New Mechanisms of Actions for Old and New DrugsGhavami, Maryam 29 June 2018 (has links)
Worldwide, malaria is one of the deadliest diseases. In 2016 it sickened 216 million people and caused 445,000 deaths. In order to control the spread of this deadly diseases to human, we can either target the mosquito vector (Anopheles gambiae) or the parasite (Plasmodium falciparum). Due to recent emergence of resistance to current insecticides and antimalarial drugs there is a pressing need to discover and develop new agents that engage new targets in these organisms.
To circumvent the effect of resistance to pyrethroid insecticides on the efficacy of insecticide treated nets (ITNs), the use of acetylcholinesterase (AChE) inhibitors on ITNs has drawn attention. In the first project, we explored a small library of γ- substituted oxoisoxazole- 2(3H)-carboxamides and isoxazol-3-yl carbamates, and nitriles as AChE inhibitors targeting wild- type (G3) and resistant (Akron) An. gambiae mosquito. In total 23 compounds were synthesized and evaluated. Both carbamates and carboximides with a 2-cyclopropylethyl side chain (1-87a and 1-88a) were extremely toxic to Akron mosquitos, yet these compounds did not exhibit appreciable selectivity between human and An. gambiae AChE. Unfortunately, none of the nitriles showed appreciable toxicity to G3 strain of the mosquitoes, nor did they inhibit An. gambiae AChE.
In the second project, conducted in collaboration with Professor Michael Klemba, we focused on the mode of action of an established antimalarial drug, Mefloquine (MQ). Dr. Klemba's recently developed amino acid efflux assay was used to determine the effect of MQ and its open-ring analogs on hemoglobin endocytosis and catabolism in P. falciparum-infected erythrocytes. In total 26 MQ analogs were synthesized and 18 were studied in depth to determine their potency to inhibit leucine (Leu) efflux and parasite growth (SYBR Green). An excellent correlation (R² = 0.98) over nearly 4 log units was seen for these 18 compounds in the two assays. These data are consistent with the hypothesis that the antimalarial action of these compounds principally derives from inhibition of hemoglobin endocytosis. After this observation, a number of photo-affinity probes were designed and synthesized in hopes of isolating the molecular target of MQ. These analogs are currently being used by Dr. Klemba in pull-down experiments.
In the third project, conducted in collaboration with Professor Belen Cassera, we sought to optimize a new antimalarial drug lead that would circumvent current resistance mechanisms. In Plasmodium parasites, the methylerythritol phosphate (MEP) pathway is known to be essential for its growth. This pathway is absent in humans, presenting the opportunity to develop potentially safe and effective therapeutic candidates. Previous work in the Cassera and Carlier lab had established that MMV008138 was the only compound in the Malaria Box that targeted the MEP pathway and that it was (1R,3S)-configured. My research expanded previous efforts in the Carlier group and produced synthesis of 73 analogs of MMV008138 (3-21a'1) that were tested for growth inhibition. These analogs featured variation at the A-, B-, C- and D-ring. In the process, a novel Pictet-Spengler ring expansion reaction of ortho-substituted acetphenones was discovered. The ring-expanded products were identified by means of 1D and 2D NMR experiments, HRMS, and X-ray crystallography. Among the 73 analogs prepared, four compounds showed similar growth inhibition potency to the lead 3-21a'1. In particular, the methoxyamide 3-80a, and the fluorinated A-ring analogs 3-124a, 3-124c and 3-124d all showed excellent (500-700 nM) growth IC₅₀ values against P. falciparum. All four showed full rescue upon co-application of IPP (200 μM), confirming that they target the MEP pathway. ADME-Tox evaluation of these new analogs will soon be underway. / PHD / Malaria is a severe and potentially fatal mosquito-borne disease. The continuous emergence of insecticide-resistant mosquitoes and drug-resistant parasite strains necessitates the development of novel antimalarial agents, notably those that engage new targets in these organisms. Herein we present three projects in which the synthesis and characterization of new malaria insecticide and therapeutic candidates are described.
Our aim in the first project was to synthesize acetylcholinesterase (AChE) inhibitors as potential mosquitocides to be deployed on insecticide-treated nets. Three different classes of compounds were synthesized and characterized. Their potency to inhibit the wild-type and insecticide-resistant mosquito AChE, and their corresponding mosquito toxicities were assessed. Mosquito-toxic compounds were identified, but they did not show appreciable selectivity between mosquito and human AChEs.
The second project was directed toward finding the biological target of a known antimalarial drug; mefloquine (MQ). Numerous different MQ analogs were synthesized, and their potency was assessed in two biochemical assays. The results of this study strongly suggest that MQ kills malaria parasites by preventing them from ingesting the red blood cell hemoglobin.
The third project was concerned with the optimization of a compound (MMV008138) that kills malaria parasites by preventing it from synthesizing a key biochemical building block (IPP). Several new compounds were prepared that had similar antimalarial activity to MMV008138, of which many have better potential to serve as antimalarial drugs. In addition, these studies provided valuable insights for the design of further improved analogs.
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