1,3-Disubstituted-tetrahydro-β-carbolines: A New Method for Stereochemical Assignment and Synthesis of Potential Antimalarial Agents

Cagasova, Kristyna

21 June 2021

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.

malaria

tetrahydro-β-carboline

IspD

MEP pathway

MMV008138

Pictet-Spengler reaction

γ-gauche effect

NMR

1H-1H coupling

bioisostere synthesis

tetrazole

phosphonic acid

Synthèse et évaluation d’inhibiteurs du transport de l’iode dans la thyroïde / Synthesis and evaluation of iodide uptake inhibitors in thyroid gland

Lacotte, Pierre

18 December 2012

L’objectif de ces travaux est de découvrir et de valoriser des petites molécules organiques inhibant l’influx de l’iode dans les cellules thyroïdiennes. Ces composés présentent en effet un double intérêt : à court terme, ils peuvent être dérivés en biosondes afin de mieux caractériser les protéines impliquées dans les mécanismes de transport d’iode par génétique chimique directe. A plus long terme, ces inhibiteurs représentent des candidats-médicaments potentiels pour le traitement de pathologies thyroïdiennes et/ou pour la protection de populations exposées aux radioisotopes de l’iode. Pour chacune des deux familles d’inhibiteurs considérées, nous avons donc tout d’abord synthétisé une chimiothèque d’une centaine d’analogues ; puis ces derniers ont été évalués biologiquement afin de fournir un ensemble de relations structure-activité. Par ailleurs, la configuration absolue des centres stéréogènes nécessaire à l’activité biologique a été déterminée : dans chacun des cas, une stéréochimie particulière est responsable du pouvoir inhibiteur des composés. A partir de ces informations, une dizaine d’analogues « de seconde génération » a été synthétisée dans chaque famille, en combinant plusieurs modifications structurales contribuant à l’activité biologique. Après évaluation biologique, neuf d’entre eux possèdent des IC50 < 6 nM et des propriétés physico-chimiques satisfaisantes pour des candidats-médicaments. Enfin, dans chaque famille, une biosonde photoactivable biotinylée a été synthétisée et utilisée en photomarquage d’affinité. Plusieurs protéines marquées spécifiquement ont été repérées, qui correspondraient à des protéines-cibles de chacun des inhibiteurs et dont l’identification reste à achever. / This work was intended to discover small organic molecules acting as iodide uptake inhibitors in thyroid cells. These compounds can indeed be derivatized into biochemical probes for further characterization of proteins involved in iodide transport mechanisms. On the long term, these inhibitors also appear as attractive drug candidates for treatment of thyroid pathologies or radioprotection against iodine isotopes. A similar strategy was adopted for both of the two inhibitor families. First, we synthesized a chemical library of around 100 analogues; we measured their IC50 against iodide uptake in FRTL-5 cells to get structure-activity relationships. Absolute configuration of stereogenic centers was also investigated, and a preferential stereochemistry was found to be responsible for activity. From this basis, around twenty « second-generation » analogues were synthesized by combining fragments contributing to biological activity. Biological evaluation indicated that nine were very potent inhibitors, with IC50 < 6 nM and satisfying physicochemical properties required for drug candidates. Finally, one photoactivatable biotinylated probe was developed in each family and used for photoaffinity labeling. Several specifically labeled proteins are still under identification and constitute new potential therapeutic targets.

Iode

Relations structure-activité

Inhibiteur

Symporteur Na+/I

Dihydropyrimidinone

Tétrahydro-β-carboline

Photomarquage d’affinité

FRTL-5

Pharmacophore

Arsenic/cérium

Iodine

Structure-activity relationships

Inhibitor

Na+/I Symporter

Dihydropyrimidinone

Tetrahydro-β-carboline

Photoaffinity labeling

, FRTL-5

, pharmacophore

Arsenic/cerium