Cellular Nucleophiles Research Articles

Autoxidation of extracellular hydroquinones is a causative event for the cytotoxicity of menadione and DMNQ in A549-S cells

Cytotoxicity of 1,4-naphthoquinones has been attributed to intracellular reactive oxygen species (ROS) generation through one-electron-reductase-mediated redox cycling and to arylation of cellular nucleophiles. Here, however, we report that in a subclone of lung epithelial A549 cells (A549-S previously called A549-G4S (Watanabe, et al., Am. J. Physiol. 283 (2002) L726–736), the mechanism of ROS generation by menadione and by 2,3-dimethoxy-1,4-naphthoquinone (DMNQ), and therefore that of cytotoxicity, differs from the paradigm. Ninety percent of H 2O 2 generation by both the quinones can be prevented by dicumarol, an inhibitor of NAD(P)H quinone oxidoreductase (NQO1), at the submicromolar level, regardless of the quinone concentrations. Exogenous SOD also inhibits H 2O 2 production at low but not high concentrations of the quinones, especially DMNQ. Thus, at low quinone concentrations, superoxide-driven hydroquinone autoxidation accounts for more than half of H 2O 2 generation by both quinones, whereas at high quinone concentrations, especially for DMNQ, comproportionation-driven hydroquinone autoxidation becomes the predominant mechanism. Hydroquinone autoxidation appears to occur predominantly in the extracellular environment than in the cytosol as extracellular catalase can dramatically attenuate quinone-induced cytotoxicity throughout the range of quinone concentrations, whereas complete inactivation of endogenous catalase or complete depletion of intracellular glutathione has only a marginal effect on their cytotoxicity. Finally, we show evidence that ROS production is a consequence of the compensatory defensive role of NQO1 against quinone arylation.

Synthesis and antimelanoma activity of tertiary amide analogues of N-acetyl-4-S-cysteaminylphenol.

The biosynthetic pathway to melanin is a realistic target for therapeutic intervention in the development of new drugs to combat malignant melanoma. N-Acetyl-4-S-cysteaminylphenol (1) is an analogue of a biosynthetic intermediate in the pathway to melanin. It probably acts as a prodrug and is oxidized selectively in melanocytes to an o-quinone, which can alkylate cellular nucleophiles resulting in interference with cell growth and proliferation. We previously synthesized a range of more lipophilic analogues of 1 by varying the acyl portion and introducing substitution alpha to the nitrogen. Most of the new compounds displayed greater cytotoxicity than the original lead compound 1. We have now prepared 12 new compounds with varying acyl portions and three different substituents on the nitrogen of the amide in order to increase lipophilicity and to reduce the possibility of hydrolysis of the amides. Most of the tertiary amides showed greater cytotoxicity towards five representative melanoma cell lines than the parent secondary amide. The highest cytotoxicity, comparable to cisplatin, was observed for the benzyl substituted compounds 4, 8, 12, and 16 and the cyclohexylacetamide derivatives 13-15 against these five cell lines. The moderate activity of 13-16 against SK-Mel-24 (non-tyrosinase containing) and an ovarian cell line suggests that interference with the melanin pathway may not be the only mode of action of these new compounds.

Indole-3-Acetic Acids and Horseradish Peroxidase: A New Prodrug / Enzyme Combination for Targeted Cancer Therapy

The radical-cations formed on one-electron oxidation of indole-3-acetic acid (IAA) and its ring-substituted derivatives rapidly fragment, eliminating carbon dioxide from the sidechain and forming a carbon-centred free radical (3-indolylmethyl or skatolyl, or analogues). This radical is reactive towards DNA and possibly other targets in anoxia, but in oxic or hypoxic cells rapidly adds oxygen to form a peroxyl radical. Subsequent products include 3-methylene-2-oxindole or analogues, reactive towards cellular nucleophiles such as thiols and DNA. The one-electron oxidation of indole-3-acetic acids is efficiently achieved by horseradish peroxidase (HRP), not requiring added hydrogen peroxide cofactor. The combination of IAA and HRP is cytotoxic towards mammalian cells, including human tumour cells. Unexpectedly, some halogen-substituted derivatives of IAA are very cytotoxic with HRP even though they are more difficult to oxidize. IAA is tolerated by humans in high doses and HRP is a robust enzyme meeting many of the requirements for targeting to tumours by coupling to antibodies or polymers, or by gene transfection. It is suggested that the indole acetic acids merit further evaluation as potential prodrugs for use in cancer therapy based on targeted delivery of HRP to tumours.

NMR Spectroscopic Analysis of the First Two Steps of the Pentose-Phosphate Pathway Elucidates the Role of 6-Phosphogluconolactonase

The pentose-phosphate pathway provides reductive power and nucleotide precursors to the cell through oxidative and nonoxidative branches, respectively. 6-Phosphogluconolactonase is the second enzyme of the oxidative branch and catalyzes the hydrolysis of 6-phosphogluconolactones, the products of glucose 6-phosphate oxidation by glucose-6-phosphate dehydrogenase. The role of 6-phosphogluconolactonase was still questionable, because 6-phosphogluconolactones were believed to undergo rapid spontaneous hydrolysis. In this work, nuclear magnetic resonance spectroscopy was used to characterize the chemical scheme and kinetic features of the oxidative branch. We show that 6-phosphogluconolactones have in fact a nonnegligible lifetime and are highly electrophilic compounds. The delta form (1-5) of the lactone is the only product of glucose 6-phosphate oxidation. Subsequently, it leads to the gamma form (1-4) by intramolecular rearrangement. However, only the delta form undergoes spontaneous hydrolysis, the gamma form being a "dead end" of this branch. The delta form is the only substrate for 6-phosphogluconolactonase. Therefore, 6-phosphogluconolactonase activity accelerates hydrolysis of the delta form, thus preventing its conversion into the gamma form. Furthermore, 6-phosphogluconolactonase guards against the accumulation of delta-6-phosphogluconolactone, which may be toxic through its reaction with endogenous cellular nucleophiles. Finally, the difference between activity of human, Trypanosoma brucei, and Plasmodium falciparum 6-phosphogluconolactonases is reported and discussed.

Pyrimido[1,2-alpha]purin-10(3H)-one: a reactive electrophile in the genome.

Malondialdehyde and base propenal react with deoxyguanosine residues in DNA to form an exocyclic adduct, pyrimido[1, 2-alpha]purin-10(3H)-one (1), that has been detected at high levels in genomic DNA of healthy humans. Previous studies have shown that tris(hydroxymethyl)aminomethane adds to 1 at elevated pH, forming an enaminoimine (2), but it is uncertain whether 1 reacts directly or hydrolyzes under basic conditions to N(2)-(3-oxo-1-propenyl)deoxyguanosine (3) prior to amine addition. We report that 1 reacts at neutral pH with hydroxylamines to form oximes. The rate of reaction of 1 with hydroxylamines at pH 7 is at least 150 times faster than the rate of hydrolysis of 1 to 3. Thus, 1 is directly reactive to nucleophiles. These observations indicate that 1 is an electrophile in the human genome that may react with cellular nucleophiles to form novel cross-linked adducts.

Protective role of dietary polyphenols in oxidative stress

The oxidative break down of the membrane polyunsaturated fatty acids is known to be accompanied by the formation of a complex mixture of lipidhydroperoxides and secondary products. These compounds are highly reactive and are capable of rapid reaction with cellular nucleophiles such as phospholipids and proteins, and it was found that these reaction products are candidates as impotant biomarkers to evaluate antioxidative activity of dietary antioxidants. The author has been involved in developing immunochemical detection methods for oxidative stress by application of polyclonal and monoclonal antibodies. From the hypothesis that endogenous antioxidants in plants must play an important role for antioxidative defense systems from oxidative stress, an intensive search for novel type of natural antioxidants has been carried out from numerous plant materials, including those used as foods, and we have isolated and identified a number of lipid-soluble and water-soluble dietary antioxidants from crop seeds, sesame seeds and some spices. In this paper, the recent progress of research on functions of dietary antioxidants is reviewed.

Drug uptake and cellular targets of hydroxymethylacylfulvene (HMAF)

Hydroxymethylacylfulvene (HMAF, MGI 114) is a novel antitumor drug and a potent pro-apoptotic agent that has the potential to alkylate cellular nucleophiles. The objective of these studies was to characterize drug uptake and cellular targets for drug binding in human leukemia CEM cells. The uptake of [ 14C]HMAF had two components: a rapid phase (0–10 min) and a slow phase. At 10 μM drug (37°), the rapid and slower phase amounted to 0.86 and 0.13 pmol/min/10 6cells, respectively. HMAF uptake was inhibited 82% by low temperature (4°) at 4 hr. Cell-associated HMAF localized to nuclear (50%), cytoplasmic (37%), and membrane fractions (10%). Continued drug uptake appeared to be driven by covalent binding to cellular macromolecules. Approximately 1/4 and 2/3 of cell-associated HMAF formed covalent adducts after 10 min and 4 hr, respectively, as found by perchloric acid precipitation. Drug adducts were not readily reversible; 77% of the covalently bound radiolabel was retained by the cells 20 hr after drug treatment. Combinations of DNase, RNase, and proteinase K with perchloric acid precipitation showed that approximately 60, 30, and 10% of the covalently bound drug was associated with the protein, DNA, and RNA fractions, respectively. Incubation of 100 μM [ 14C]HMAF (24 hr) with purified DNA, serum albumin, thioredoxin, and thioredoxin reductase resulted in 6, 22, 14, and 11 pmol [ 14C]HMAF/μg DNA or protein, respectively. Results indicate that multiple targets for HMAF binding may contribute to the pro-apoptotic and antiproliferative action of the drug.

Mechanism of inhibition of rat liver class 2 ALDH by 4-hydroxynonenal.

Lipid oxidation is a pathological process that results in the peroxidation of cellular membrane lipids ultimately giving rise to a number of reactive, cytotoxic, aldehydic products (Esterbauer et al, 1991). 4-hydroxy-2-trans-nonenal (4-HNE) malondialdehyde (MDA), the most abundant aldehydes produced during lipid peroxidation, have a relatively long half-life and are capable of diffusing to distant sites within the cell of origin or into adjacent cells. 4-HNE can produce a variety of adverse cellular effects which have b summarized in detail elsewhere (Schauer et al, 1990) and include the inhibition of various enzymes (Vander Jagt et al, 1997). The ability of certain biogenic aldehydes to produce diverse biological and cytotoxic effects can be attributed to their α, β-unsaturated configuration that gives the compounds strong electrophilic properties (Esterbauer et al, 1991).us, investigators attribute these adverse effects to the formation of aldehyde ad- ducts h cellular protein nucleophiles through covalent alkylation of sulfhydryl, primary amino, and histidyl groups of proteins (Hartley et al, 1997; Uchida and Stadtman, 1993).

Interindividual variability in P450-dependent generation of neoantigens in halothane hepatitis

Halothane hepatitis occurs because susceptible patients mount immune responses to trifluoroacetylated protein antigens, formed following cytochrome P450-mediated bioactivation of halothane to trifluoroacetyl chloride. In the present study, an in vitro approach has been used to investigate the cytochrome P450 isozyme(s) which catalyze neoantigen formation and to explore the protective role of non-protein thiols (cysteine and reduced glutathione). Significant levels of trifluoroacetyl protein antigens were generated when human liver microsomes, and also microsomes from livers of rats pre-treated with isoniazid, phenobarbital or β-naphtoflavone, were incubated with halothane plus a nicotinamide adenine dinucleotidephosphate (NADPH) generating system. Immunoblotting studies revealed that the major trifluoroacetyl antigens expressed in vitro exhibited molecular masses of 50–55 kDa and included 60 and 80 kDa neoantigens recognized by antibodies from patients with halothane hepatitis. Much lower concentrations of halothane were required to produce maximal antigen generation in isoniazid-induced rat microsomes, as compared with phenobarbital or isosafrole-induced microsomes (0.5 vs 12.5 μl/ml). In isoniazid-induced microsomes, antigen generation was inhibited >90% by the nucleophiles cysteine and glutathione and by the CYP2E1-selective inhibitors diallylsulfide and p-nitrophenol, but was unaffected by inhibitors of other P450 isozymes (furafylline, sulfaphenazole or triacetyloleandomycin). Neoantigen formation in six human liver microsomal preparations was inhibited in the presence of diallylsulfide, but not by furafylline, sulfaphenazole or triacetyloleandomycin, and exhibited marked variability which correlated with CYP2E1 levels. These results suggest that the balance between metabolic bioactivation by CYP2E1 and detoxication of reactive metabolites by cellular nucleophiles could be an important metabolic risk factor in halothane hepatitis.

Naphthazarin derivatives: synthesis, cytotoxic mechanism and evaluation of antitumor activity.

The rate of the GSH conjugate formation, the inhibition of DNA topoisomerase-I and the cytotoxic activity against L1210 cells of the naphthoquinones showed the same order; 5,8-dimethoxy-1,4-naphthoquinone (DMNQ) > 6-(1-hydroxyethyl)-DMNQ > 2-(1-hydroxyethyl)-DMNQ; the steric hindrance of the substituents, particularly 2-substutuent, in reacting with cellular nucleophiles must be the main cause for lowering the bioactivities. Acetylation of 2-(1-hydroxyethyl)-DMNQ producing 2-(acetyloxyethyl)-DMNQ potentiated the bioactivities; 2-(1-hydroxyethyl)-DMNQ did not react with GSH and the enzyme, and showed ED50 of 0.680 microgram/ml, whereas the values of 2-(1-acetyloxyethyl)-DMNQ were the conjugate formation of 0.14 microM, IC50 value of 81 microM for the enzyme inhibition and ED50 of 0.146 microgram/ml for the cytotoxcity. Furthermore, the acetylation 2-(1-hydroxyethyl)-DMNQ (T/C, 119%) enhanced the T/C values for the mice bearing S-180 tumor [T/C of 2-(1-acetyloxyethyl)-DMNQ, 276%]. It was assumed that the difference in bioactivities ensued by acetylation was based on the mechanism of the so-called bioreductive alkylation.

Transcriptional activity of quinone methides derived from the tumor promoter butylated hydroxytoluene in HepG2 cells

Butylated hydroxytoluene (BHT) is a pulmonary toxin and tumor promoter in mice presumably due to the formation of two quinone methides (QMs) that alkylate cellular nucleophiles. The activation of stress genes by these electrophilic metabolites was investigated with an assay system consisting of 14 recombinant cell lines derived from the human hepatoma line HepG2, each carrying a unique promoter or response element construct fused to the reporter gene for chloramphenicol acetyl transferase (CAT). The largest responses to QMs occurred in cells containing either the metallothionein IIA, glutathione S-transferase Ya, or 70 kDa heat shock protein promoter, or the xenobiotic response element. The other cell lines exhibited only small or no effects. These results are consistent with transcriptional activities reported for several other electrophiles known to undergo covalent interactions with proteins.

The reactivity of o-quinones which do not isomerize to quinone methides correlates with alkylcatechol-induced toxicity in human melanoma cells

Catechols are widespread in the environment, especially as constituents of edible plants. A number of these catechols may undergo oxidative metabolism to electrophilic o-quinones (3,5-cyclohexadien-1,2-dione) by oxidative enzymes such as cytochrome P450 and peroxidases. Alkylation of cellular nucleophiles by these intermediates and the formation of reactive oxygen species, especially through redox cycling of o-quinones, could contribute to the cytotoxic properties of the parent catechols. In contrast, isomerization of the o-quinones to electrophilic quinone methides (4-methylene-2,5-cyclohexadien-1-one, QM) could cause cellular damage primarily through alkylation. In this investigation, we treated human melanoma cells with two groups of catechols. These cells have high levels of tyrosinase required to oxidize catechols to quinoids. For catechols which are oxidized to o-quinones that cannot isomerize to quinone methides or form unstable quinone methides, plots of the cytotoxicity data (ED 50) versus the reactivity of the o-quinones gave an excellent linear correlation; decreasing o-quinone reactivity led to a decrease in the cytotoxic potency of the catechol. In contrast, catechols which are metabolized by the o-quinone/ p-quinone methide bioactivation pathway were equally cytotoxic but showed no correlation between the reactivity of the o-quinones and the cytotoxic potency of the catechols. The most likely explanation for this effect is a change in cytotoxic mechanism from o-quinone-mediated inhibition of cell growth to a bioactivation pathway based on both o-quinone and p-QM formation. These results substantiate the conclusion that the involvement of the o-quinone/QM pathway in catechol toxicity depends on a combination between the rate of enzymatic formation of the o-quinone, the rate of isomerization to the more electrophilic QM, and the chemical reactivity of the quinoids.

Monocrotaline Metabolism and Distribution in Fisher 344 and Sprague-Dawley Rats

The metabolism and distribution of 14C-monocrotaline in Fisher 344 (F344) rats was compared with that in Sprague-Dawley (SD) rats. In vitro microsomal preparations, in situ isolated perfused livers and in vivo excretion and distribution studies were used to discern any differences between these two strains. These strains have previously been shown to differ in their susceptibility to monocrotaline-induced pulmonary hypertension. Hepatic phase I metabolism appears to be similar in both strains with N-oxidation and dehydrogenation to the reactive pyrroles as the major pathways. During the liver perfusions, SD rats generated more monocrotalic acid than F344 rats, but the microsome and excretion studies demonstrated no significant differences in the amount of monocrotalic acid. Monocrotalic acid is a stable byproduct of dehydromonocrotaline reacting with cellular nucleophiles and indicates the amount of monocrotaline dehydrogenation when carboxylesterase activity is negligible. These data suggest that the differences in strain susceptibility to pulmonary vascular toxicity is most likely due to differences in their response to the toxic metabolites.

Covalent Modification of Proteins and Peptides by the Quinone Methide from 2-tert-Butyl-4,6-dimethylphenol: Selectivity and Reactivity with Respect to Competitive Hydration

Covalent modification of cellular nucleophiles by electrophilic metabolites has been shown to be an important pathway in the toxicological activity of many xenobiotic compounds. The p-quinone methi...

Structure-activity relationships in the hydrolysis of acrylate and methacrylate esters by carboxylesterase in vitro

Acrylate esters are important chemicals in the plastics industry, whose toxicity is theorized to involve alkylation of critical cellular nucleophiles via the Michael addition. Carboxylesterase-mediated hydrolysis of acrylates may be a detoxification mechanism as the unsaturated acid produced is not electrophilic under physiological conditions. Using purified porcine liver carboxylesterase, the enzymatic hydrolysis of several acrylate esters was characterized to determine Km and Vmax values for each ester. The Km (μM) and Vmax (nmol/min) values observed for ethyl acrylate were 134 ± 16 (S.D.) and 8.9 ± 2.0, respectively. While the Km for ethyl methacrylate was not significantly different, the Vmax, 5.5 ± 2.5, was significantly lower compared with the corresponding value for ethyl acrylate. The Km and Vmax for butyl acrylate were 33.3 ± 8.5 μM and 1.49 ± 0.83 nmol/min, respectively, and the corresponding values for its α-methyl analog were not significantly different. The Km and Vmax for tetraethyleneglycol dimethacrylate were 39 ± 15 μM and 2.9 ± 1.0 nmol/min, respectively. The Vmax for ethyleneglycol dimethacrylate, 6.9 ± 2.4 nmol/min, was significantly higher than that of the larger bifunctional ester tetraethyleneglycol dimethacrylate, but the Km was not significantly different. These results indicate that α-methyl substitution appears to have a minor effect in the enzymatic hydrolysis of acrylates, and suggest that the relative toxicity of acrylates is not due to differences in carboxylesterase-mediated hydrolysis.

Influence of the Halogen-Substituent Pattern of Fluoronitrobenzenes on Their Biotransformation and Capacity to Induce Methemoglobinemia

In the present study both the biotransformation patterns and the capacity to induce methemoglobinemia of a series of fluoronitrobenzenes were investigated. This was done to investigate to what extent variation in the number and position of the halogen substituents influence the metabolic fate of the fluoronitrobenzenes, thereby influencing their capacity to induce methemoglobinemia. The results obtained were compared to the effect of the fluorine substituent patterns on the calculated electronic characteristics and, thus, on the chemical reactivity of the fluoronitrobenzenes. Analysis of thein vivometabolic profiles demonstrates a dependence of the extent of nitroreduction, of glutathione conjugation, and of aromatic hydroxylation with the pattern of halogen substitution. With an increasing number of fluorine substituents at electrophilic carbon centers, 24-hr urine recovery values decreased and fluoride anion elimination increased, due to increased reactivity of the fluoronitrobenzenes with cellular nucleophiles.In vitrostudies even demonstrated a clear correlation between calculated parameters for the electrophilicity of the fluoronitrobenzenes and the natural logarithm of their rate of reaction with glutathione or with bovine serum albumin, taken as a model for cellular nucleophiles (r= 0.97 andr= 0.98, respectively). Increased possibilities for the conjugation of the fluoronitrobenzenes to cellular nucleophiles were accompanied by decreased contributions of nitroreduction and aromatic hydroxylation to the overallin vivometabolite patterns, as well as by a decreased capacity of the fluoronitrobenzenes to induce methemoglobinemia.In vitrostudies on the rates of nitroreduction of the various fluoronitrobenzenes by cecal microflora and rat liver microsomes revealed that the changes in the capacity of the fluoronitrobenzenes to induce methemoglobinemia were not due to differences in their intrinsic reactivity in the pathway of nitroreduction, leading to methemoglobinemia-inducing metabolites. Thus, the results of the present study clearly demonstrate that the number and position of fluorine substituents in the fluoronitrobenzenes influence the capacity of the fluoronitrobenzenes to induce methemoglobinemia, not because their intrinsic chemical reactivity for entering the nitroreduction pathway is influenced. The different methemoglobinemic capacity must rather result from differences in the inherent direct methemoglobinemic capacity and/or reactivity of the various toxic metabolites and/or from the fact that the halogen substituent pattern influences the electrophilic reactivity, thereby changing the possibilities for reactions of the nitrobenzenes with glutathione and, especially, other cellular nucleophiles. When the number of fluorine substituents increases, the electrophilicity of the fluoronitrobenzenes can become so high that glutathione conjugation is no longer able to compete efficiently with covalent binding of the fluoronitrobenzenes to cellular macromolecules. As a consequence, it can be suggested that with an increasing number of fluorine substituents at electrophilic carbon centers in a nitrobenzene derivative, a toxic end point of the nitrobenzene other than formation of methemoglobinemia can be foreseen.

Michael Acceptors as a Tool for Anticancer Drug Design

Abstract: Interaction of antitumor drugs with cellular targets involves various types of chemical binding, of which covalent binding is one of important strategies in designing effective anticancer molecules. The anticancer compounds employing covalent binding, structurally diverse, belong to many chemical classes, including quinones, mustards, nitrosourea, alkylsulfonate, pyrrolo[l,4]benzodiazepines, and others. Most of these compounds contain, or acquire by cellular metabolism, electrophilic centers, and some are Michael acceptors in a broader sense. Recent evidences suggest that antineoplastic alkylating compounds bind directly to various cellular nucleophiles, thus lacking in a selectivity. Meanwhile, Michael acceptors can be structurally modified, so that they can react selectively with target nucleophiles or they can be converted into a selective Michael acceptors during metabolism. Moreover, we often meet these Michael acceptors in biochemical process of cellular respiration or in metabolisms of some drugs or xenobiotics. A group of representative natural cytotoxic compounds containing Michael acceptor are naphthoquinones such as menadione and shikonin analogues, cytotoxic quassinoids, sesquiterpenoid benzoquinones, and others. Mitomycin, meanwhile, is transformed by reductive activation into a conjugated dienone as a Michael acceptor. In this review, chemistry, cytotoxicity and antitumor action of anticancer agents containing Michael acceptors will be discussed in the respect of structure-activity relationship. More in-depth review will be given of the naphthazarin analogues. Also, cytotoxic terpenes such as ar-turmerone analogues, quassinoids, and others will be reviewed.

Formation of adducts between 13-oxooctadecadienoic acid (13-OXO) and protein- derived thiols, in vivo and in vitro

Linoleic acid is metabolized by numerous tissues to oxidized derivatives possessing biological activity. In the current experiments, we have investigated the reaction of 13-oxooctadecadienoic acid (13-OXO) and the metabolic precursor 13-hydroxyoctadecadienoic acid (13-HODE) with cellular macromolecules and model cellular nucleophiles. Colonie mucosal expiants from Sprague-Dawley rats were incubated in the presence of [1− 14C]-13-OXO or [1- 14C]-13-HODE. The binding of radiolabel to the protein and nucleic acid fractions was analyzed by isopycnic centrifugation in CS 2SO 4. Cellular homogenates incubated with either 13-OXO or 13-HODE resulted in the binding of radiolabel to cellular protein. No significant amounts of reaction with cellular RNA or DNA were observed. To assess possible modes of reaction with cellular constituents, the oxidized fatty acids were incubated in vitro with oxygen, sulfur, or nitrogen nucleophiles including, serine, cysteine, glutathione, methionine, lysine, adenosine, and guanosine. Under physiologic conditions, in the absence of cellular homogenates, only 13-OXO was reactive. In addition, only the sulfur-containing compounds cysteine and glutathione showed significant rates of reaction. Furthermore, treatment of colonic homogenates with N-ethylmaleimide reduced the binding of [1− 14C]-13-OXO to cellular protein. These data support the suggestion that 13-HODE requires metabolic activation, by dehydrogenation to 13-OXO, prior to binding to cellular protein and that protein-derived thiol groups are involved in the binding reactions.

Reaction of trifluoroacetaldehyde with amino acids, nucleotides, lipid nucleophiles, and their analogs.

Trihaloacetaldehydes are used as sedatives, are key intermediates in the metabolism of 1,1,1,2-tetrahaloethanes, some of which are chlorofluorocarbon substitutes, and are metabolites of trihaloethanols, which are intestinal and bone marrow toxins. In the present study, trifluoroacetaldehyde was used as a model to examine the reactions of trihaloacetaldehydes with cellular nucleophiles, including amino acids, nucleotides, and lipid components. Reaction of trifluoroacetaldehyde hydrate (10 mM) with amino acids (100 mM) in buffer at pH 7.0 and 30 degrees C showed that only L-cysteine formed stable adducts, which were identified as (2R,4R)- and (2S,4R)-2-(trifluoromethyl)thiazolidine-4-carboxylic acid. The absolute stereochemistry of (2R,4R)- and (2S,4R)-2-(trifluoromethyl)thiazolidine-4-carboxylic acid was determined by homonuclear Overhauser effect experiments. The diastereoisomers were formed in a 2.8:1 ratio at 37 degrees C and in a 1:4.0 ratio at 80 degrees C. Trifluoroacetaldehyde also reacted with L-cysteine methyl ester and 2-mercaptoethylamine to form stable thiazolidine derivatives, but did not react with N-acetyl-L-cysteine. The reaction of trifluoroacetaldehyde with the amino groups of ATP, GMP, CMP, L-citrulline, and urea resulted in the formation of stable imines. TMP, which lacks an exocyclic amino group, did not react. Glutathione reacted with trifluoroacetaldehyde to form (2R,5R)- and (2S,5R)-5-amino-6-[carboxymethyl)imino]-2-(trifluoromethyl)-1,3- oxathiane, whose formation was accompanied by simultaneous cleavage of the glutamyl moiety. The reactivity of nucleophilic groups with trifluoroacetaldehyde follows the order SH > NH2 > OH. The results of the present study indicate that trifluoroacetaldehyde covalently modifies cellular nucleophiles. The biological significance of these reactions warrants further investigation. The reaction of trifluoroacetaldehyde with L-cysteine and glutathione may afford routes for the stereoselective synthesis of cysteine prodrugs and five- or six-membered heterocyclic compounds.

Cell-cycle specific cytotoxicity mediated by rearranged ent-kaurene diterpenoids isolated from Parinari curatellifolia

Two structurally novel cytotoxic ent-kaurene diterpenoids, 13-methoxy-15-oxozoapatlin and 13-hydroxy-15-oxozoapatlin, were isolated from the root bark of Parinari curatellifolia, together with the known compound, 15-oxozoapatlin, on the basis of bioactivity-guided Chromatographic fractionation and found to demonstrate broad-spectrum cytotoxic activity against a panel of cultured human cancer cell lines. The structures of these compounds were determined by analysis of their spectroscopic data. The presence of an α,β-unsaturated carbonyl group in 13-methoxy-15-oxozoapatlin suggested that the cytotoxic potential of this compound could be mediated through reaction with cellular nucleophiles by means of a Michael-type addition. The compound 13-methoxy-15-oxozoapatlin reacted with the nucleophiles L-cysteine and β-mercaptoethanol. The adduct with β-mercaptoethanol was isolated, structurally characterized and found to be ~ 5-fold less cytotoxic than 13-methoxy-15-oxozoapatlin itself. The compound 13-methoxy-15-oxozoapatlin did not interact with DNA nor guanosine, and it was not mutagenic for Salmonella typhimurium strain TM677. The effects of 13-methoxy-15-oxozoapatlin on the growth of human cancer cells were analyzed utilizing cultured ZR-75-1 breast cancer cells. Biosynthesis of DNA, RNA and protein was reduced in treated cells, and accumulation at the G 2/M phase of the cell cycle was observed. The compound 13-methoxy-15-oxozoapatlin did not mediate antimitotic activity with dibutyryl cAMP-treated cultured astrocytoma cells, suggesting that the cell cycle effect is G 2 specific. No antitumor activity was observed when athymic mice carrying KB cells were treated with 13-methoxy-15-oxozoapatlin. These data indicate that the cytotoxic activity of 13-methoxy-15-oxozoapatlin is mediated in part by covalent reaction with a cellular component (such as a sulfhydryl-containing protein) by means of a Michael-type addition, and this results in the blockage of cell-cycle progression.