Dexter Morin

Mechanisms and Pathology of Monocrotaline Pulmonary Toxicity

Monocrotaline (MCT) is an 11-membered macrocyclic pyrrolizidine alkaloid (PA) that causes a pulmonary vascular syndrome in rats characterized by proliferative pulmonary vasculitis, pulmonary hypertension, and cor pulmonale. Current hypotheses of the pathogenesis of MCT-induced pneumotoxicity suggest that MCT is activated to a reactive metabolite(s) in the liver and is then transported by red blood cells (RBCs) to the lung, where it initiates endothelial injury. While several lines of evidence support the requirement of hepatic metabolism for pneumotoxicity, the mechanism and relative importance of RBC transport remain undetermined. The endothelial injury does not appear to be acute cell death but rather a delayed functional alteration that leads to disease of the pulmonary arterial walls by unknown mechanisms. The selectivity of MCT for the lung, as opposed to that of other primarily hepatotoxic PAs, appears likely to be a consequence of the differences in hepatic metabolism and blood kinetics of MCT. A likely candidate for a reactive metabolite of MCT is the dehydrogenation product monocrotaline pyrrole (MCTP). Secondary or phase II metabolism of MCT through glutathione (GSH) conjugation has been characterized recently and appears to represent a detoxification pathway. The role of inflammation in the progression of MCT-induced pulmonary vascular disease is uncertain. Both perivascular inflammation and platelet activation have been proposed as processes contributing to the response of the vascular media. This review presents the experimental evidence supporting these hypotheses and outlines additional questions that arise from them.

Involvement of cytochrome P450 3A in the metabolism and covalent binding of 14C‐monocrotaline in rat liver microsomes

The metabolism and covalent binding of 14C‐monocrotaline in Sprague–Dawley (SD) rat liver microsomes was investigated using the inducers dexamethasone, clotrimazole, pregnenolone‐16α‐carbonitrile, and phenobarbital. Monocrotaline is a pyrrolizidine alkaloid (PA) that causes a syndrome in rats that is a model for human primary pulmonary hypertension. It has been documented that bioactivation of PAs (dehydrogenation to reactive pyrroles) in the liver by cytochromes P450 is required for their toxicity. Covalent binding of these reactive pyrroles to tissue macromolecules has been hypothesized to correspond to PA toxicosis. We correlated metabolism and total microsomal covalent binding of 14C‐monocrotaline with cytochrome P450 3A using the aforementioned inducers, troleandomycin (a cytochrome P450 3A inhibitor), erythromycin N‐demethylase assay of cytochrome P450 3A activity, and Western blots employing anti‐rat cytochrome P450 3A antibodies. In addition, autoradiography of membranes electroblotted from SDS‐PAGE demonstrated the formation of radiolabeled adducts with specific protein(s). The most intensely radiolabeled protein bands have an apparent molecular weight of ∼52 kDa, which was similar to the molecular weight detected by anti‐rat cytochrome P450 3A antibodies in the Western blots. No radiolabeled proteins were detected in microsomes pretreated with troleandomycin.

Isolation and identification of a pyrrolic glutathione conjugate metabolite of the pyrrolizidine alkaloid monocrotaline

This report describes the isolation and identification of a monocrotaline-derived, glutathione-conjugated pyrrole obtained from the bile of male Sprague-Dawley rats. Bile obtained from rats given an intravenous bolus of 14C-monocrotaline was fractionated using a series of chromatographic separations. Initial purification with cholestyramine resin removed bile acid and pigment contaminants. Subsequent anion exchange and reversed-phase HPLC separations yielded several fractions that contained the 14C label and tested positive for pyrroles using Ehrlichs reagent. These fractions were analyzed using fast-atom-bombardment tandem mass spectrometry (FAB MS/MS). In addition to glutathione-conjugated dehydroretronecine, at least one other pyrrole present had similar ionic properties. The latter was not present in amounts sufficient for positive identification.

Red blood cells augment transport of reactive metabolites of monocrotaline from liver to lung in isolated and tandem liver and lung preparations

Monocrotaline (MCT) is a pyrrolizidine alkaloid that causes pulmonary hypertension in rats by mechanisms which remain largely unknown. MCT is thought to be activated in the liver to a reactive intermediate that is transported to the lung where it causes endothelial injury. Our previous pharmacokinetic work demonstrated significant sequestration of radioactivity in red blood cells (RBCs) of rats treated with [14C]MCT. To determine whether this RBC sequestration might be important in the transport of reactive MCT metabolites, we compared the effect of inclusion of RBCs in the perfusion buffer on the extent of covalent binding of [14C]MCT to rat lungs in tandem liver-lung preparations. The potential effect of RBCs in stabilizing reactive intermediates was evaluated by preperfusion of isolated liver preparations with [14C]MCT with and without RBCs, separation and washing of the RBC fraction, and subsequent (90 min later) perfusion of washed RBCs or buffer alone in isolated perfused lungs. Covalent binding to lung tissues was determined by exhaustive methanol/chloroform extractions of unbound label from homogenized lung tissue followed by scintillation counting of residual 14C. Covalent binding was expressed as picomole MCT molecular weight equivalents/mg protein. Comparison of the relative capability of these isolated organ preparations for conversion of MCT to polar metabolites was done by extraction and HPLC analysis of perfusate at the end of the experiment. Isolated livers converted 65-85% of MCT to polar metabolites compared with less than 5% conversion in the isolated lungs. Inclusion of RBCs in the buffer of tandem lung liver preparations perfused with 400 microM [14C]MCT increased the covalent binding to the lung from 97 +/- 25 (buffer alone) to 182 +/- 36 (buffer + RBC) pmol/mg protein. At the end of these perfusions, RBCs contained 1552 +/- 429 pmol/mg hemoglobin of which 333 +/- 98 pmol/mg hemoglobin resisted exhaustive solvent extraction. After 90 min at room temperature, buffer with 400 microM [14C]MCT preperfused in isolated livers resulted in covalent binding to isolated perfused lung of 0.8 +/- 0.4 pmol/mg protein while washed RBCs isolated from buffer of similar liver preperfusions preparations resulted in 53 +/- 7 pmol/mg protein bound to lung. Control groups perfused with 400 microM [14C]MCT in buffer or buffer + RBCs through isolated lungs only resulted in covalent binding of 2 +/- 1 or 1 +/- 0.6 pmol/mg protein respectively. We conclude: (1) RBCs significantly augment the transport of lung reactive MCT metabolites from the liver to the lung.(ABSTRACT TRUNCATED AT 400 WORDS)

Development of Metabolically Stable Inhibitors of Mammalian Microsomal Epoxide Hydrolase

The microsomal epoxide hydrolase (mEH) plays a significant role in the metabolism of xenobiotics such as polyaromatic toxicants. Additionally, polymorphism studies have underlined a potential role of this enzyme in relation to a number of diseases, such as emphysema, spontaneous abortion, eclampsia, and several forms of cancer. We recently demonstrated that fatty amides, such as elaidamide, represent a new class of potent inhibitors of mEH. While these compounds are very active on recombinant mEH in vitro, they are quickly inactivated in liver extracts reducing their value in vivo. We investigated the effect of structural changes on mEH inhibition potency and microsomal stability. Results obtained indicate that the presence of a small alkyl group alpha to the terminal amide function and a thio-ether beta to this function increased mEH inhibition by an order of magnitude while significantly reducing microsomal inactivation. The addition of a hydroxyl group 9-10 carbons from the terminal amide function resulted in better inhibition potency without improving microsomal stability. The best compound obtained, 2-nonylsulfanyl-propionamide, is a competitive inhibitor of mEH with a K I of 72 nM. Furthermore, this new inhibitor significantly reduces mEH diol production in ex vivo lungs exposed to naphthalene, underlying the usefulness of the inhibitors described herein. These novel inhibitors could be valuable tools to investigate the physiological and biological roles of mEH.

Toxicity and metabolism of methylnaphthalenes: Comparison with naphthalene and 1-nitronaphthalene

Naphthalene and close structural analogues have been shown to cause necrosis of bronchiolar epithelial cells in mice by both inhalation exposure and by systemic administration. Cancer bioassays of naphthalene in mice have demonstrated a slight increase in bronchiolar/alveolar adenomas in female mice, and in inflammation and metaplasia of the olfactory epithelium in the nasal cavity. Similar work in rats demonstrated a significant, and concentration-dependent increase in the incidence of respiratory epithelial adenomas and neuroblastomas in the nasal epithelium of both male and female rats. Although the studies on the acute toxicity of the methylnaphthalene derivatives are more limited, it appears that the species selective toxicity associated with naphthalene administration also is observed with methylnaphthalenes. Chronic administration of the methylnaphthalenes, however, failed to demonstrate the same oncogenic potential as that observed with naphthalene. The information available on the isopropylnaphthalene derivatives suggests that they are not cytotoxic. Like the methylnaphthalenes, 1-nitronaphthalene causes lesions in both Clara and ciliated cells. However, the species selective lung toxicity observed in the mouse with both naphthalene and the methylnaphthalenes is not seen with 1-nitronaphthalene. With 1-nitronaphthalene, the rat is far more susceptible to parenteral administration of the compound than mice. The wide-spread distribution of these compounds in the environment and the high potential for low level exposure to humans supports a need for further work on the mechanisms of toxicity in animal models with attention to whether these processes are applicable to humans. Although it is tempting to suppose that the toxicity and mechanisms of toxicity of the alkylnaphthalenes and nitronaphthalenes are similar to naphthalene, there is sufficient published literature to suggest that this may not be the case. Certainly the enzymes involved in the metabolic activation of each of these substrates are likely to differ. The available data showing extensive oxidation of the aromatic nucleus of naphthalene, nitronaphthalene and the methylnaphthalenes (with some oxidation of the methyl group) contrast with the isopropylnaphthalene derivatives, where the major metabolites involve side chain oxidation. Overall, these data support the view that ring epoxidation is a key step in the process involved in cytotoxicity. Whether the epoxide itself or a downstream metabolite mediates the toxic effects is still not clear even with naphthalene, the best studied of this group of compounds. Additional work is needed in several areas to further assess the potential human health consequences of exposure to these agents. These studies should involve the definition of the extent and severity of methylnaphthalene toxicity after single dose exposures with attention to both the nasal and respiratory epithelia. The cytochromes P450 responsible for the initial activation of these agents in rodents with subsequent complimentary studies in primate models should help determine whether key metabolic processes responsible for toxicity occur also in primates. Finally, the precise involvement of reactive metabolite formation and adduction of cellular proteins in toxicity will be important in not only assessing the potential for human toxicity, but also in developing an understanding of the genetic and environmental factors which could alter the toxicity of these agents.

Proteomic identification, cDNA cloning and enzymatic activity of glutathione S-transferases from the generalist marine gastropod, Cyphoma gibbosum.

Glutathione S-transferases (GST) were characterized from the digestive gland of Cyphoma gibbosum (Mollusca; Gastropoda), to investigate the possible role of these detoxification enzymes in conferring resistance to allelochemicals present in its gorgonian coral diet. We identified the collection of expressed cytosolic Cyphoma GST classes using a proteomic approach involving affinity chromatography, HPLC and nano-spray liquid chromatography-tandem mass spectrometry (LC-MS/MS). Two major GST subunits were identified as putative mu-class GSTs; while one minor GST subunit was identified as a putative theta-class GST, apparently the first theta-class GST identified from a mollusc. Two Cyphoma GST cDNAs (CgGSTM1 and CgGSTM2) were isolated by RT-PCR using primers derived from peptide sequences. Phylogenetic analyses established both cDNAs as mu-class GSTs and revealed a mollusc-specific subclass of the GST-mu clade. These results provide new insights into metazoan GST diversity and the biochemical mechanisms used by marine organisms to cope with their chemically defended prey.

Formation of covalently bound protein adducts from the cytotoxicant naphthalene in nasal epithelium: species comparisons.

Background Naphthalene is a volatile hydrocarbon that causes dose-, species-, and cell type–dependent cytotoxicity after acute exposure and hyperplasia/neoplasia after lifetime exposures in rodents. Toxicity depends on metabolic activation, and reactive metabolite binding correlates with tissue and site susceptibility. Objectives We compared proteins adducted in nasal epithelium from rats and rhesus macaques in vitro. Methods Adducted proteins recovered from incubations of nasal epithelium and 14C-naphthalene were separated by two-dimensional (2D) gel electrophoresis and imaged to register radioactive proteins. We identified proteins visualized by silver staining on complementary nonradioactive gels by peptide mass mapping. Results The levels of reactive metabolite binding in incubations of rhesus ethmoturbinates and maxilloturbinates are similar to those in incubations of target tissues, including rat septal/olfactory regions and murine dissected airway incubations. We identified 40 adducted spots from 2D gel separations of rat olfactory epithelial proteins; 22 of these were nonredundant. In monkeys, we identified 19 spots by mass spectrometry, yielding three nonredundant identifications. Structural proteins (actin/tubulin) were prominent targets in both species. Conclusions In this study we identified potential target proteins that may serve as markers closely associated with toxicity. The large differences in previously reported rates of naphthalene metabolism to water-soluble metabolites in dissected airways from mice and monkeys are not reflected in similar differences in covalent adduct formation in the nose. This raises concerns that downstream metabolic/biochemical events are very similar between the rat, a known target for naphthalene toxicity and tumorigenicity, and the rhesus macaque, a species similar to the human.

Chemoprevention of tobacco smoke-induced lung tumors by inhalation of an epigallocatechin gallate (EGCG) aerosol: A pilot study

We investigated whether inhalation of aerosolized epigallocatechin gallate (EGCG) would prevent the development of lung tumors produced by tobacco smoke (TS). Male strain A/J mice were exposed for 5 mo, 6 h/day, 5 days/wk, to a mixture of tobacco sidestream and mainstream smoke. At the end of this exposure, 3 groups were formed: (a) mice exposed to TS and left undisturbed in air; (b) animals exposed to TS and given EGCG aerosol by nose-only inhalation for 30 min per session; and (c) animals exposed to TS and then exposed by nose-only inhalation to water aerosol without any EGCG (sham-exposed group). Three similar groups were formed from animals that previously had been kept in filtered air. In experiment 1, the EGCG concentration in the aerosol was 80 μg/L and administered 3 times a week and in experiment 2 it was 191 μ g/L administered twice a week. Inhalation of EGCG did not modulate TS-induced tumorigenesis. In two accompanying positive control experiments, animals treated with the tobacco-specific carcinogen NNK [4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone] were given the same EGCG or water aerosol treatment. In both experiments, EGCG aerosol significantly reduced lung tumor multiplicity by 20% to 30% However, exposure of NNK-treated animals to water solvent alone (sham exposure) produced an even greater reduction in tumor multiplicities (40%). A reduction of lung tumor multiplicities was also observed in animals exposed nose-only once or five times a week to either water aerosols or to filtered air. It is concluded that water-soluble chemopreventive agents that need to be ingested in comparatively high doses are not the most suitable candidates for administration by inhalation.

Age-Specific Effects on Rat Lung Glutathione and Antioxidant Enzymes after Inhaling Ultrafine Soot

Vehicle exhaust is rich in polycyclic aromatic hydrocarbons (PAHs) and is a dominant contributor to urban particulate pollution (PM). Exposure to PM is linked to respiratory and cardiovascular morbidity and mortality in susceptible populations, such as children. PM can contribute to the development and exacerbation of asthma, and this is thought to occur because of the presence of electrophiles in PM or through electrophile generation via the metabolism of PAHs. Glutathione (GSH), an abundant intracellular antioxidant, confers cytoprotection through conjugation of electrophiles and reduction of reactive oxygen species. GSH-dependent phase II detoxifying enzymes glutathione peroxidase and glutathione S-transferase facilitate metabolism and conjugation, respectively. Ambient particulates are highly variable in composition, which complicates systematic study. In response, we have developed a replicable ultrafine premixed flame particle (PFP)-generating system for in vivo studies. To determine particle effects in the developing lung, 7-day-old neonatal and adult rats inhaled 22 μg/m(3) PFP during a single 6-hour exposure. Pulmonary GSH and related phase II detoxifying gene and protein expression were evaluated 2, 24, and 48 hours after exposure. Neonates exhibited significant depletion of GSH despite higher initial baseline levels of GSH. Furthermore, we observed attenuated induction of phase II enzymes (glutamate cysteine ligase, glutathione reductase, glutathione S-transferase, and glutathione peroxidase) in neonates compared with adult rats. We conclude that developing neonates have a limited ability to deviate from their normal developmental pattern that precludes adequate adaptation to environmental pollutants, which results in enhanced cytotoxicity from inhaled PM.