Improvement of a biomimetic porphyrin catalytic system by addition of acids

A versatile and recyclable molecularly imprinted polymer as an oxidative catalyst of sulfur derivatives: a new possible method for mustard gas and V nerve agent decontamination

A molecularly imprinted polymer containing a porphyrin unit was developed as a biomimetic heterogenous catalyst for the oxidation of sulfur derivatives. Its catalytic efficiency under mild conditions and its easy recovery represent a great asset for the design of new decontamination tools for yperite and VX.

Investigating the mode of action of the redox-active antimalarial drug plasmodione using the yeast model

Malaria is caused by protozoan parasites and remains a major public health issue in subtropical areas. Plasmodione (3-[4-(trifluoromethyl)benzyl]-menadione) is a novel early lead compound displaying fast-acting antimalarial activity. Treatment with this redox active compound disrupts the redox balance of parasite-infected red blood cells. In vitro, the benzoyl analogue of plasmodione can act as a subversive substrate of the parasite flavoprotein NADPH-dependent glutathione reductase, initiating a redox cycling process producing ROS. Whether this is also true in vivo remains to be investigated. Here, we used the yeast model to investigate the mode of action of plasmodione and uncover enzymes and pathways involved in its activity. We showed that plasmodione is a potent inhibitor of yeast respiratory growth, that in drug-treated cells, the ROS-sensitive aconitase was impaired and that cells with a lower oxidative stress defence were highly sensitive to the drug, indicating that plasmodione may act via an oxidative stress. We found that the mitochondrial respiratory chain flavoprotein NADH-dehydrogenases play a key role in plasmodione activity. Plasmodione and metabolites act as substrates of these enzymes, the reaction resulting in ROS production. This in turn would damage ROS-sensitive enzymes leading to growth arrest. Our data further suggest that plasmodione is a pro-drug whose activity is mainly mediated by its benzhydrol and benzoyl metabolites. Our results in yeast are coherent with existing data obtained in vitro and in Plasmodium falciparum, and provide additional hypotheses that should be investigated in parasites.

Gadolinium Acetylacetonate Tetraphenyl Monoporphyrinate Complex and Some of Its Derivatives: EXAFS Study and Molecular Dynamics Simulation

Many attempts to obtain single crystals appropriate for X-ray diffraction analysis of the Ln(tpp)(acac) derivatives (where Ln = Gd or Sm, tpp = tetraphenylporphyrin and acac = acetylacetonate) have failed so far. A suitable way to get structural parameters for these monoporphyrinates is to use extended X-ray absorption fine structure (EXAFS) spectroscopy. We recorded spectra of the monoporphyrins, Ln(tpp)(acac) and Gd(tpyp)(acac) (where tpyp = tetrapyridylporphyrin), and the bisporphyrin GdH(tpyp)2 in the solid state. We particularly focused our structural analysis on Gd(tpp)(acac), applying both molecular modeling and EXAFS, which allowed us to get accurate results about the local environment of the central atom. The Gd3+ ion of the complex at room temperature was found to be bonded to four monoporphyrin nitrogen atoms at an average distance R(Gd-N(av)) = 2.48 A and to three or four oxygen atoms at R(Gd-O(ac,w)) = 2.38 A from an acetylacetonato anion and a water molecule. The presence of the second water molecule in the coordination sphere was barely discernible by EXAFS analysis. Molecular modeling has provided further information about the coordination core geometry of the Gd(tpp)(acac) monoporphyrinate, including a bishydrated coordination sphere. Also, it has enabled the construction of a 3D structural model on which multiple scattering analyses were attempted. Monte Carlo simulation was used to validate the adjustments. EXAFS spectra analysis was carried out on the derivatives, displaying slight distortions in the lanthanide central-atom coordination geometry.

Les catalyseurs porphyriniques : un outil pour la préparation de modèles de métabolites

The porphyrin complexes of manganese catalysts are biomimetic catalysts whose structural analogy with the active site of cytochrome P-450 enzymes can be used to obtain synthetic models of therapeutic agent metabolites. Mn(TDCOO)Cl, a second generation porphyrin, has proven robust enout to be used for scaled-up production in the presence of hydrogen peroxide and imidazole. For this purpose, an improvement in substrate oxidation was obtained by adjunction of formic acid to the reaction medium which preserved the cocatalyst and the catalyst. It was shown that addition of acid played an active role in the oxidation process. After this optimization, the system was used to oxidate the two enantiomers of methyloctalone, an essential chiral intermediate in the synthesis of terpenoids and steroids. The efficacy of this biomimetic method for the preparation of large amounts of oxidized chiral synthons was better than obtained with biological ex vivo pathways.

Regio- and diastereocontrolled preparative oxidation of methyloctalones by a biomimetic porphyrin catalyst

Both enantiomers of methyloctalone were oxidized by a biomimetic manganese/porphyrin/imidazole catalytic system in order to obtain sufficient amounts of various model metabolites. The double bond proved to be less sensitive than the ring methylenes. Hydroxylation occurred mainly in the allylic position (position 8) and also at positions 7 and 6. In position 8, two diastereomers were obtained while in positions 7 and 6 the reaction was diastereospecific. In the case of position 8 only the oxidation yielded a keto compound. The efficiency of this method for the preparation of functionalized chiral synthons was better than it was for biological pathways.

Comparison of the efficiency of various methods for the synthesis of models of metabolites: example of 4a-methylhexahydronaphtalenones

In order to examine the biotransformations of xenobiotics, it is essential to realize studies of metabolism of drugs in living animals. It is generally difficult to extract quantitatively the metabolites from biological media or excreta. Alternative methods have then been developed. Application of such techniques to 4a-methylhexahydronaphthalenones, which constitute starting material for the stereospecific synthesis of terpenoids or steroids, is particularly demonstrative. By biosynthetical ways, it was not possible to access with good yields to all the metabolites obtained in vivo. A novel methodology, based on the use of a manganoporphyrin catalyst, allowed to synthesize large amounts of several models of metabolites corresponding to those which had been isolated in living rats. Only one of the metabolites obtained in vivo could not be synthesized by this biomimetic system. This proved that alternative methods are precious to obtain models with good yields, but need to be validated by controls in living animals.