Luís Constantino

Memantine reduces oxidative damage and enhances long-term recognition memory in aged rats

Many neurodegenerative diseases, including Alzheimers (AD), Parkinsons (PD) and Huntingtons diseases (HD), are caused by different mechanisms but may share a common pathway to neuronal injury as a result of the overstimulation of glutamate receptors. It has been suggested that this pathway can be involved in generation of cognitive deficits associated with normal aging. Previous studies performed in our laboratory have demonstrated that aged rats presented recognition memory deficits. The aim of the present study was to evaluate the effect of memantine, a low-affinity N-methyl-D-aspartate (NMDA) receptor antagonist, on age-induced recognition memory deficits. Additionally, parameters of oxidative damage in cerebral regions related to memory formation were evaluated. In order to do that, male Wistar rats (24 months old) received daily injections of saline solution or memantine (20 mg/kg i.p.) during 21 days. The animals were submitted to a novel object recognition task 1 week after the last injection. Memantine-treated rats showed normal recognition memory while the saline group showed long-term recognition memory deficits. The results show that memantine is able to reverse age-induced recognition memory deficits. We also demonstrated that memantine reduced the oxidative damage to proteins in cortex and hippocampus, two important brain regions involved in memory formation. Thus, the present findings suggest that, at least in part, age-induced cognitive deficits are related to oxidative damage promoted by NMDA receptor overactivation.

Metabolism of primaquine by liver homogenate fractions. Evidence for monoamine oxidase and cytochrome P450 involvement in the oxidative deamination of primaquine to carboxyprimaquine.

The role of monoamine oxidase (MAO) and cytochrome P450 (P450) in the oxidative deamination of primaquine by rat liver fractions was studied. Rat liver fractions including liver homogenate, mitochondria, microsomes and 100,000 g supematant fractions were prepared from a pool of rat livers and characterised using benzylamine as a probe for MAO activity and N,N-dimethylbenzamide as a probe for P450 N-dealkylation activity. Incubation of all fractions with primaquine yielded carboxyprimaquine as the only metabolite detectable by HPLC. The mitochondrial fraction, which contained MAO activity but not P450 activity, presented the highest Vmax/K(M) value for the formation of carboxyprimaquine (8.5 x 10(-6) dm3mg(-1)h(-1). A substantially lower Vmax/K(M) value (1.3 x 10(-6) dm3mg(-1)h(-1)) was obtained in the microsomal fraction, which contained P450 but not MAO activity. The liver homogenate fraction presented a similar value (1.8 x 10(-6) dm3mg(-1)h(-1), though it contained both enzyme systems. Incubations of all the fractions that presented MAO activity, in presence of the MAO inhibitor pargiline, resulted in a marked inhibition of primaquine oxidation. P450 inhibitor SKF 525-A effectively inhibited primaquine metabolism in the microsomal fraction but inhibition in the liver homogenate was less effective. The results are consistent with an important role for MAO in primaquine biotransformation, though clearly metabolism by P450 has a contribution role.

Lipophilic pyrazinoic acid amide and ester prodrugs Stability, activation and activity against M. tuberculosis

Pyrazinamide (PZA) is active against M. tuberculosis and is a first line agent for the treatment of human tuberculosis. PZA is itself a prodrug that requires activation by a pyrazinamidase to form its active metabolite pyrazinoic acid (POA). Since the specificity of cleavage is dependent on a single bacterial enzyme, resistance to PZA is often found in tuberculosis patients. Esters of POA have been proposed in the past as alternatives to PZA however the most promising compounds were rapidly degraded in the presence of serum. In order to obtain compounds that could survive during the transport phase, we synthesized lipophilic ester and amide POA derivatives, studied their activity against M. tuberculosis, their stability in plasma and rat liver homogenate and also their activation by a mycobacterial homogenate. The new lipophilic ester prodrugs were found to be active in concentrations 10-fold lower than those needed for PZA to kill sensitive M. tuberculosis and also have a suitable stability in the presence of plasma. Amides of POA although more stable in plasma have lower activity. The reason can probably be found in the rate of activation of both types of prodrugs; while esters are easily activated by mycobacterial esterases, amides are resistant to activation and are not transformed into POA at a suitable rate.

Dipeptide derivatives of primaquine as transmission-blocking antimalarials : Effect of aliphatic side-chain acylation on the gametocytocidal activity and on the formation of carboxyprimaquine in rat liver homogenates

AbstractPurpose. Dipeptide derivatives of primaquine (PQ) with reduced oxidative deamination to the inactive metabolite carboxypnmaquine were synthesized and evaluated as a novel class of transmission-blocking antimalarials. Methods. Antimalarial activity was studied using a model consisting of mefloquine-resistant Plasmodium berghei ANKA 25R/10, Balb C mice, and Anopheles stephensi mosquitoes. Metabolic studies were performed with rat liver homogenates, and the incubates were analyzed by HPLC. Results. All dipeptide derivatives and glycyl-PQ completely inhibited the appearance of oocysts in the midguts of the mosquitoes at 15 mg/ kg, while N-acetylprimaquine was not active at this dose. However, none of the title compounds were able to block oocyst production at 3.75 mg/kg, in contrast with primaquine. Exception for sarc-gly-PQ, all remaining compounds prevented sporozoite formation in the salivary glands of mosquitoes at a dose of 3.75 mg/kg. Simultaneous hydrolysis to primaquine and gly-PQ ocurred with the following order of Vmax/ Km: for primaquine formation, L-ala-gly-PQ > L-phe-gly-PQ > gly-gly-PQ; and for gly-PQ formation, L-phe-gly-PQ > L-ala-gly-PQ > gly-gly-PQ. In contrast, primaquine was not released from D-phe-gly-PQ, sarc-gly-PQ, and N-acetylprimaquine. Neither carboxyprimaquine nor 8-amino- 6-methoxy- quinoline were detected in any of the incubation mixtures. Conclusions. The title compounds prevent the development of the sporogonic cycle of Plasmodium berghei. Gametocytocidal activity is independent of the rate and pathway of primaquine formation. Acylation of the aliphatic side-chain effectively prevents the formation of Carboxyprimaquine, but the presence of a terminal amino group appears to be essential for the gametocytocidal activity.

The microsomal demethylation of N,N-dimethylbenzamides: Substituent and kinetic deuterium isotope effects

The metabolism of N,N-dimethylbenzamides by phenobarbital-induced rat liver microsomes results in the formation of N-methylbenzamides and formaldehyde. The reaction proceeds via the formation of an intermediate N-hydroxymethyl-N-methylbenzamide, which, for the microsomal oxidation of N,N-dimethylbenzamide, was isolated and characterized. Confirmation of the N-hydroxymethyl-N-methylbenzamide was obtained by its independent synthesis from N-methylbenzamide and formaldehyde. The intermolecular kinetic deuterium isotope effects for the reaction are 0.9 (+/- 0.1) for Vmax and 1.4 (+/- 0.1) for Vmax/Km. The intramolecular kinetic deuterium isotope effect, determined from the relative amounts of N-methylbenzamide and N-trideuteriomethylbenzamide formed in the microsomal demethylation of N-trideuteriomethyl-N-methylbenzamide, is 6.0 +/- 0.3. There is no correlation of Vmax or Vmax/Km with the substituent in the aromatic ring, nor with the calculated ionization potentials of the benzamides. The results are interpreted in terms of a mechanism in which the benzamide undergoes direct hydrogen atom abstraction to form a carbon centred radical. This carbon centred radical subsequently forms an N-hydroxymethyl-N-methylbenzamide that decomposes to formaldehyde and an N-methylbenzamide. Semi-empirical AM1 self consistent field molecular orbital calculations identify that loss of a hydrogen atom from the E-methyl group is thermodynamically more favourable than from the Z-methyl group by ca. 5 kJ/mol.

A carbamate-based approach to primaquine prodrugs: antimalarial activity, chemical stability and enzymatic activation.

O-Alkyl and O-aryl carbamate derivatives of the antimalarial drug primaquine were synthesised as potential prodrugs that prevent oxidative deamination to the inactive metabolite carboxyprimaquine. Both O-alkyl and O-aryl carbamates undergo hydrolysis in alkaline and pH 7.4 phosphate buffers to the parent drug, with O-aryl carbamates being ca. 10(6)-10(10) more reactive than their O-alkyl counterparts. In human plasma O-alkyl carbamates were stable, whereas in contrast their O-aryl counterparts rapidly released the corresponding phenol product, with primaquine being released only slowly over longer incubation periods. Activation of the O-aryl carbamates in human plasma appears to be catalysed by butyrylcholinesterase (BuChE), which leads to carbamoylation of the catalytic serine of the enzyme followed by subsequent slow enzyme reactivation and release of parent drug. Most of the O-aryl and O-alkyl carbamates are activated in rat liver homogenates with half-lives ranging from 9 to 15 h, while the 4-nitrophenyl carbamate was hydrolysed too rapidly to determine an accurate rate constant. Antimalarial activity was studied using a model consisting of Plasmodium berghei, Balb C mice and Anopheles stephensi mosquitoes. When compared to controls, ethyl and n-hexyl carbamates were able to significantly reduce the percentage of infected mosquitos as well as the mean number of oocysts per infected mosquito, thus indicating that O-alkyl carbamates of primaquine have the potential to be developed as transmission-blocking antimalarial agents.

Microsomal metabolism of N,N-diethyl-m-toluamide (DEET, DET): the extended network of metabolites.

1. The aim was to set out to establish the complete network of metabolites arising from the phenobarbital-treated rat liver microsomal oxidation of N,N-diethyl-m-toluamide (DEET). The products formed from DEET and all its subsequent metabolites were identified by HPLC retention times, UV spectroscopy, mass spectrometry and by comparison with authentic standards. 2. DEET (1a) produces three major metabolites, N-ethyl-m-toluamide (1b), N,N-diethyl-m-(hydroxymethyl)benzamide (2a) and N-ethyl-m-(hydroxymethyl)benzamide (2b), and, at low substrate concentrations or extended reaction times, two minor metabolites, toluamide (1c) and N,N-diethyl-m-formylbenzamide (3a). 1b and 2a are primary metabolites and their formation follows Michaelis-Menten-type kinetics. At low DEET concentrations, ring methyl group oxidation is favoured; at saturation concentrations, methyl group oxidation and N-deethylation proceed at similar rates. The rate of formation of 2b decreases with increasing DEET concentration; 2b is therefore a secondary metabolite of DEET and DEET acts as a competitive inhibitor of the metabolism of 1b and 2a. 3. Except for the primary amides, where N-dealkylation is impossible, metabolism of all subsequent compounds, 1b,c, 2a-c, 3a-c and 4a,b, involves an N-deethylation (NEt2 --> NHEt or NHEt --> NH2) competitive with a ring substituent oxidation (CH3 --> CH2OH, CH2OH --> CHO or CHO --> CO2H). Surprisingly, the aldehydes 3a-c are also reduced to the corresponding alcohols 2a-c (CHO --> CH2OH); CO inhibits the oxidative metabolism of 3a-c, but reduction to 2a-c continues uninhibited. 4. The outcomes of this work are that (1) previously unreported aldehydes 3b and 3c form part of the DEET network of metabolites, (2) the reduction of the aldehydes 3a-c has the potential to inhibit the formation of the more highly oxidized DEET metabolites, (3) amide hydrolysis was not observed for any substrate and (4) no evidence was obtained for N-(1-hydroxyethyl)amide intermediates.

The microsomal dealkylation of N,N-dialkylbenzamides.

The in vitro metabolism of N,N-dialkylamides by phenobarbital-induced rat liver microsomes yields an N-alkylamide and the corresponding aldehyde. Although, N-hydroxymethyl-N-alkylamide intermediates can be detected from N-methyl-N-alkylamides, no N-hydroxyalkyl-N-alkylamide intermediates are detected from the N,N-dialkylamide substrates. Vmax values were independent of amide structure, whereas Vmax/Km values were dependent on the lipophilicity of the N,N-dialkylbenazamide studied. These results suggest that diffusion of substrate into the membrane-bound enzyme active site limits the rate of microsomal oxidation of the amides. Metabolism of N-alkyl-N-methylamides reveals identical values of Vmax for demethylation and dealkylation. Values of Vmax/Km for demethylation depend upon the lipophilicity of the N-alkyl group, whereas Vmax/Km values for dealkylation appear to be dependent upon the steric bulk of the alkyl group, particularly around the alpha-carbon. Moreover, Vmax/Km values for demethylation are larger than for dealkylation, implying the reactions are under kinetic control. Comparison of the kinetic data with theoretical AM1 semi-empirical molecular orbital calculations suggests a mechanism involving formation of a carbon-centred radical. Use of an N-cyclopropylmethylbenzamide substrate to trap such a radical failed, presumably because oxygen rebound is faster than radical rearrangement. An N-cyclopropylamide substrate did not undergo metabolism of the cyclopropyl ring, consistent with carbon-centred radical, but not nitrogen radical cation, formation.

In vitro metabolism of diphenyl diselenide in rat liver fractions. Conjugation with GSH and binding to thiol groups

In spite of an extensive literature reporting pharmacological properties of diphenyl diselenide, (PhSe)(2), little is known about its metabolism. The aim of this study was to identify possible metabolic pathways of (PhSe)(2) in vitro to get insights into the mechanism of its toxicity. Rat liver preparations, namely total homogenate, S9 fraction, cytosol and microsomes were used in the incubations. Samples were analyzed using liquid chromatography-tandem mass spectrometry (LC-MS/MS), high-performance liquid chromatography (HPLC) or inductively coupled plasma (ICP). A reduced glutathione (GSH)-selenol adduct (m/z 462) was identified in all liver fraction incubations by LC-MS/MS, suggesting a reaction between (PhSe)(2) and GSH in tissues. Results from incubation of (PhSe)(2) with microsomal fraction showed that (PhSe)(2) disappears from the supernatant without formation of phase I metabolites. The addition of exogenous GSH maintained constant (PhSe)(2) levels in supernatant and significantly reduced the amount of selenium in the precipitate obtained when microsomal incubations were treated with methanol. Addition of N-acetylcysteine (NAC) had a similar effect; moreover, a NAC-selenol adduct similar to the GSH-selenol adduct was identified by LC-MS/MS (m/z 318) in the NAC incubations. The data indicates that (PhSe)(2) probably binds covalently to microsomal components and that GSH and NAC can prevent binding. The depletion of GSH levels in vitro may be related to (PhSe)(2) toxicity. The inhibition of cytochrome P450 (CYP) activity by carbon monoxide or proadifen did not change the amount of (PhSe)(2) in supernatant and selenium levels in the precipitate, neither did the inactivation of the microsomes by heat indicating that binding was not mediated by cytochrome P450 metabolism and was probably due to a direct reaction between (PhSe)(2) and microsomal components. Due to the covalent binding of (PhSe)(2) to microsomal components the potential of (PhSe)(2) to inhibit cytochrome P450 was examined. (PhSe)(2) at a concentration as low as 1 μM reduced monooxygenase activity with an IC(50) value of 78 μM.

Oxidation of the methyl groups of N,N-dimethylbenzamides by a cytochrome P450 mono-oxygenase model system

Abstract Oxidation of N,N -dimethylbenzamides to the corresponding N -formyl- N -methylbenzamides using tetraphenylporphyrinato-iron(III)-Bu t OOH is independent of the substituent in the aryl ring of the benzamide group and subject to a kinetic deuterium isotope effect of 5.6. These results are consistent with a mechanism involving direct hydrogen atom abstraction from the substrate.