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Metabolic labelling of bacterial isoprenoids produced by the methylerythritol phosphate pathway : a starting point towards a new inhibitor / Marquage métabolique des isoprénoïdes bactériens produits par la voie du méthylérythritol phosphate : un point de départ vers un nouvel inhibiteurBaatarkhuu, Zoljargal 05 September 2017 (has links)
Les isoprénoïdes, présents dans tous les organismes vivants, sont synthétisés selon deux processus: la voie du Mevalonate et la voie Méthylérythritol phosphate (MEP). Cette dernière, absente chez l’humain, est très étudiée car elle représente une cible pour le développement de nouveaux antimicrobiens. Le ME-N3, un analogue du méthylérythritol portant un azoture, a été synthétisé et exploité dans des expériences de marquage métabolique de la voie MEP en utilisant un couplage bioorthogonale suivi d’une analyse par LC/MS. De façon intéressante, nous avons découvert que le MEP-N3, un analogue du MEP, inhibe l'enzyme IspD d’ E. coli (3ème enzyme de la voie MEP). Les études cinétiques ont révélé que le MEP-N3 possède la meilleure activité inhibitrice sur IspD d’ E.coli en comparaison avec les inhibiteurs connus, et que le mécanisme d'inhibition est de type mixte. Une étude détaillée du mécanisme de la réaction catalysée par IspD a été réalisée pour la première fois, en utilisant une analyse cinétique à deux substrats. / Isoprenoids, present in all living organisms, are synthesised according to two routes: the Mevalonate and the Methylerythritol phosphate (MEP) pathways. The MEP pathway, absent in humans, is extensively investigated as it is a target for the development of new antimicrobials. ME-N3 an azide tagged analogue of methylerythritol was synthesised and utilised for metabolic labelling studies of the MEP pathway using bioorthogonal ligation followed by LC-MS analysis. Interestingly, we found that MEP-N3, an analogue of MEP, inhibits E.coli IspD (3rd enzyme of the MEP pathway). Further inhibition kinetic studies revealed that MEP-N3 possesses the highest inhibitory activity on E.coli ispD when compared to known inhibitors. In addition, the mechanism of inhibition of E.coli ispD by MEP-N3 was found to be best described using a mixed type model. Moreover, determination of the IspD reaction mechanism has been carried out for the first time, by virtue of a bisubstrate steady state kinetic analysis.
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Enzymes in the Mycobacterium tuberculosis MEP and CoA Pathways Targeted for Structure-Based Drug DesignBjörkelid, Christofer January 2012 (has links)
Tuberculosis, caused by the pathogenic bacteria Mycobacterium tuberculosis, is one of the most widespread and deadly infectious diseases today. Treatment of tuberculosis relies on antibiotics that were developed more than 50 years ago. These are now becoming ineffective due to the emergence of antibiotic resistant strains of the bacteria. The aim of the research in this thesis was to develop new antibiotics for tuberculosis treatment. To this end, we targeted enzymes from two essential biosynthetic pathways in M. tuberculosis for drug development. The methylerythritol phosphate (MEP) pathway synthesizes a group of compounds called isoprenoids. These compounds have essential roles in all living organisms. The fact that humans utilize a different pathway for isoprenoid synthesis makes the MEP pathway enzymes attractive targets for drug development. We have determined the structures of two essential enzymes from this pathway by X-ray crystallography: 1-deoxy-D-xylulose 5-phosphate reductoisomerase (DXR) and 2-C-methyl-D-erythritol 4-phosphate cytidylyltransferase (IspD). These are the first structures of these enzymes from M. tuberculosis. Additionally, structures of the IspD enzyme from the related bacteria Mycobacterium smegmatis were determined. We have characterized these enzymes and evaluated the efficiency of a number of inhibitors of the DXR enzyme by biochemical methods. Crystal structures of DXR in complex with some of these inhibitors were also determined. The second pathway of interest for drug development is the universal pathway for Coenzyme A biosynthesis. Enzymes in this pathway have essential roles in all living organisms. However, the bacterial enzymes have little similarity to the human homologues. We have determined a number of structures of the M. tuberculosis pantothenate kinase (PanK), the regulatory enzyme of this pathway, in complex with two new classes of inhibitory compounds, and evaluated these by biochemical methods. The structures and biochemical characterization of these enzymes provide us with detailed information about their functions and broadens our knowledge of these bacteria. Biochemical and structural information about new inhibitors of these enzymes serve as a starting point for future development of antibiotics against tuberculosis.
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MMV008138 and analogs: potential novel antimalarial agents for P. falciparumLiu, Lixuan 15 May 2018 (has links)
Malaria is a severe and deadly mosquito-borne disease. Although treatable, the continuous emergence of multi-drug resistant parasite strains urgently calls for the development of novel antimalarial agents. P. falciparum parasites synthesize essential isoprenoid precursors, isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP), via a non-mevalonate pathway: the methylerythritol phosphate (MEP) pathway. This pathway is not utilized by humans. Thus, compounds that target the MEP pathway and disrupt isoprenoid biosynthesis in P. falciparum hold promise as potent and safe new antimalarial agents, that engage new targets.
Previously, we and others identified MMV008138 from the Malaria Box as a MEP pathway targeting compound. Later work revealed that it targets the IspD enzyme within the MEP pathway. Work in the Carlier group has established preliminary structure-activity relationship (SAR) of MMV008138: 1) (1R,3S)-configuration is required; 2) 2', 4'-disubstitution of the D-ring with small, electronegative substituents; 3) functional importance of carboxylate acid at C3.
In this work, I aim to gain further insight into the C3 SAR and A-ring SAR of lead compound MMV008138. Synthesized acid bioisosteres and A-ring analogs of MMV008138 were evaluated in their ability to inhibit P. falciparum parasite growth. We showed that the C3 substituent of MMV008138 has a very tight SAR, and likely interacts with a very constricted pocket within the PfIspD enzyme. A-ring modifications are limited to certain positions of MMV001838 and need to be sterically small. However, we have yet to identify a modification that significantly improves drug lead potency.
Future work will continue towards understanding the A-ring SAR of MMV008138, as well as D-ring SAR and C1-SAR. Efforts will also be directed towards finding analogs with improved potency, transport and metabolic stability. / MS / Malaria is a severe and deadly mosquito-borne disease, caused by malaria parasites. Although treatable, the continuous emergence of drug resistance urgently calls for the development of novel antimalarial agents. Research in the Carlier group is aimed at finding drug molecules that can selectively target and kill the malarial parasite, and at the same time be safe to humans. The Carlier group has identified MMV008138 from the Malaria Box as a promising drug lead. In this work, I aim to understand the how the structure of MMV008138 play a role in its ability to kill malaria parasites. These results will help identify modification strategies that may significantly improve drug lead potency.
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Novel Antimalarial Compounds from the Optimization of the Malaria BoxDing, Sha 27 August 2020 (has links)
Malaria continues to threaten human beings, causing a staggering number of more than 400,000 deaths each year. Although effective treatment and prevention methods are available, rapidly emerging resistance towards existing drugs is of great concern, and the need for novel antimalarial compounds are still urgent. The Malaria Box lead molecules MMV008138 and MMV665831 are promising in this regard, due to their apparently novel antimalarial mechanisms of action.
The target of MMV008138 is the PfIspD enzyme in the MEP pathway, which is absent in humans. This difference makes the PfIspD a great target. However, while MMV008138 shows potency against Plasmodium falciparum-infected human erythrocytes in vitro, no efficacy was observed in a humanized mouse model or a P. berghei infected mouse in vivo. In order to block potential metabolic spots and to probe for steric demand, a series of analogous featuring C1-deuteration, methyl substitution on B- and C-ring, and an ethylene bridge were prepared. The effect of various substitution on the tetrahydro-β-carboline conformation and D-ring orientation was studied.
In the course of preparing the C1-Me analog of MMV008138 featuring 2',4'- dichloro substitution, unexpected ring-expanded azepane products were isolated. Later it was found that the desired product could be isolated when the imine formed was treated with acid at lower temperature. Other intermediates possessing a 2ʹ- substituent were also isolated under the low temperature acid treatment protocol,
which upon heating in acid gave the ring-expanded azepane we initially isolated. A mechanism was proposed to account for the formation of the azepane as well as other intermediates. The driving force of the expansion reaction was explored, and the hypothesis that the steric interaction between the 2ʹ-substituent and the C1-Me was supported via DFT calculation and conformational analysis.
MMV665831 is another potent hit from the Malaria Box, and it appears to inhibit the hemoglobin endocytosis process of P. falciparum. The structure–activity relationship of MMV665831 was studied with analogues featuring modifications on C2-benzamide, C3-ester, C-7 phenol, as well as the phenolic Mannich base moiety. Modifications at phenolic Mannich base moiety leads to the discovery of an analogue that is twice as potent toward cultured P. falciparum compared to MMV665831. We were worried the phenolic Mannich base moiety might act as the precursor of toxic quinone methide intermediates, and designed two analogs to block this potential toxicophore. Although the modification resulted in reduced potency, this result proved that the potency of MMV665831 does not stem from the formation of quinone methides. Unfortunately, MMV665831 did not reduce parasitemia in P. berghei- infected mice. Fast hepatocyte metabolism was observed for MMV665831, and the loss of in vivo efficacy was discussed in comparison with other phenolic Mannich bases with similar hepatocyte stability. / Doctor of Philosophy / In the fight against malaria, one concerning issue is the rapidly emerging resistance towards existing drugs. The continuous development of antimalarials with novel mechanism of action is greatly needed. To accelerate the development of novel antimalarials, an open access ensemble of 400 compounds that are toxic to the malaria parasite known as the Malaria Box, has been made available. My work involves the optimization of two compounds from this ensemble, MMV008138 and MMV665831.
MMV008138 kills the malaria parasite by inhibiting an enzyme named PfIspD, which is absent in human. In the parasite an enzyme called PfIspD is responsible for the biosynthesis of IPP and DMAPP, two chemical building blocks that are essential for all cells. It is unlikely that MMV008138 will interrupt with the biosynthesis of IPP and DMAPP in human, since we use another enzyme to synthesize them. Although MMV008138 shows great in vitro potency, but did not protect a live mouse from malaria infection. The lack of in vivo efficacy could stem from the rapid metabolism of MMV008138, and analogs aimed to prevent metabolism were designed and prepared. While preparing analogs featuring 2ʹ-substitution, the desired product was not found, but other unexpected by-products were isolated. The conditions that leads to both the desired products and the by-products were found, and the mechanistics detail of this unexpected reaction were studied.
During the blood-stage, which causes malaria symptoms in human, the Plasmodium falciparum parasite invades and feeds on human red blood cells (erythrocytes). The parasite destroys human hemoglobin through a multistep process that begins by transporting the hemoglobin from the red blood cell into itself, a process called endocytosis. MMV665831 appears to interfere with this endocytosis process of P. falciparum, thus starving the parasite of its food. Analogs of MMV665831 were prepared to probe for the effect on potency, and one compound that is twice as potent in cultured parasites was found. The structure of MMV665831 contains a potentially unstable moiety, which might lead to toxicity in humans. Two analogs with the problematic moiety removed were designed and prepared, and one still shows antimalarial activity, showing that the reactivity of the potentially unstable moiety is not the reason for the antimalarial activity of MMV665831. However, MMV665831did not protect P. berghei-infected mice (murine malaria) in vivo, and the reason for the loss of efficacy was discussed.
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1,3-Disubstituted-tetrahydro-β-carbolines: A New Method for Stereochemical Assignment and Synthesis of Potential Antimalarial AgentsCagasova, Kristyna 21 June 2021 (has links)
Malaria is a serious mosquito-borne disease affecting the majority of Earth's southern hemisphere. While consistent efforts to curb malaria spread throughout 20th and early 21st century were largely successful, the recent rise in resistance to antimalarial treatments resulted in an increasing incidence rate and stalling mortality rate. This trend clearly signifies the need for the development of novel antimalarial agents able to circumvent current drug-resistance mechanisms.
In 2014, in collaboration with Prof. Maria Belen Cassera from the University of Georgia, our group found that compound 1a (1R,3S-MMV008138), discovered from the publicly available Malaria Box, targets an essential biosynthetic pathway (MEP pathway) of malaria-causing parasite Plasmodium falciparum. Analogs of 1a synthesized in our laboratory were found effective against multi-resistant Dd2 strain of P. falciparum which, together with an absence of MEP pathway in humans, suggests that potent analogs of 1a may be safe and efficient antimalarial drug candidates.
The initial bioassay studies determined that only one of four possible MMV008138 stereoisomers satisfactorily inhibits the target PfIspD enzyme. Thus a secure determination of stereochemistry in 1a analogs was of utmost importance to the structure-activity relationship studies performed in our group. The second chapter of this work discusses the validation of the previously known empirical stereoassignment method based on analysis of relative shift of 13C NMR resonances between cis and trans diastereomers and compares it to a new method based on 3JHH coupling constants developed in our laboratory. We demonstrate that the new method relying on the analysis of 1H-1H coupling is reliable over large samples of experimental data and suitable even when only a single diastereomer is produced in the synthetic process. Importantly, the origin of 3JHH coupling constants is well understood, unlike the source of relative differences in 13C NMR shifts observed in the older method. The empirical observations for both stereoassignment methods are supported by extensive density-functional theory calculations, which validate the new 1H-1H coupling-based assignment but do not provide a conclusive explanation for the origin of the 13C NMR-based method.
In the third chapter, we discuss the replacement of the carboxylic acid moiety in 1a by alternative functional groups promising improved toxicity and bioavailability profile. The total synthesis of tetrazole (trans-23a) and phosphonic acid ((±)-62a) derivatives of 1a is discussed in detail. The tetrazole analog 23a was previously synthesized in the Carlier group as a diastereomeric mixture of cis and trans isomers (dr = 3:7), and it was tested for growth inhibition of multi-resistant P. falciparum with promising results. Later, the synthesis was revisited to obtain a stereochemically pure sample of trans-23a, which was expected to show improved potency compared to the original sample. Furthermore, the synthesis of pure trans-23a confirmed the accuracy of the previous assignment of cis and trans diastereomers in the mixture. Unfortunately, neither analog showed an improvement in potency relative to 1a. / Doctor of Philosophy / The most severe form of malaria disease is caused by the parasite, Plasmodium falciparum, which gives rise to over 200 million infections and more than 400 thousand deaths every year, the majority of which affect young children. In recent years, the effectiveness of clinically used antimalarial medicines decreased due to an increase in drug-resistant strains of P. falciparum. Therefore, there is an urgent need for new antimalarial agents that could bypass the emerging resistance.
A promising candidate for a new antimalarial drug is a molecule named MMV008138. This molecule exists in four distinct forms called stereoisomers. Stereoisomers are molecules with the same chemical formula, but the atoms in each molecule are positioned differently. Only one of MMV008138's four stereoisomers (1a) was effective in killing the P. falciparum. The second chapter of this work discusses a new method for identifying stereoisomers in molecules like MMV008138. We demonstrate that the new method is both reliable and simpler than the previously used procedures.
The third chapter of this dissertation discusses the preparation of two new compounds based on the structure of 1a that contain modifications promising improved biological activity. Unfortunately, neither of these two molecules was able to kill the P. falciparum efficiently.
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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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