Biotransformation enzymes in nasal mucosa and liver of Sprague-Dawley rats

Tissue-Specific Metabolism of Benzene in Zymbal Gland and Other Solid Tumor Target Tissues in Rats

In vitro studies were carried out to investigate whether target organ susceptibility to benzene-induced solid tumor formation is governed by tissue-specific differences in metabolism. The ability of several target and nontarget tissues to deconjugate and conjugate polar metabolites, to metabolize benzene to phenolic metabolites, to carry out peroxidative biotransformations, and to trap tissue glutathione was evaluated. The Zymbal gland, the organ most sensitive to benzene-induced tumorigenicity, showed extensive phenyl- and aryl-sulfatase activity but no phenol sulfoconjugating activity. Similarly, oral cavity tissue, mammary gland, and bone marrow showed sulfatase activity but lacked sulfotransferase activity. Sulfatase-mediated hydrolysis such as that observed in the Zymbal gland may represent an important pathway by which polar metabolites are shunted from urinary or biliary excretion as their sulfates to delivery to target tissues as phenolic or potentially reactive metabolite(s). Zymbal gland, nasal and oral cavity, and mammary gland tissue homogenates (10,000 g supernatant) all possess oxidative capability to metabolize benzene to phenol, hydroquinone, and catechol. Nasal cavity homogenates produced two-to eightfold higher levels of phenol, hydroquinone, and catechol from benzene than did liver homogenates. Zymbal gland, bone marrow, and oral cavity homogenates, when incubated with hydroquinone and glutathione, produced high levels of 2-(S-glutathionyl)hydroquinone, indirectly indicating the production of 1,4-benzoquinone, a reactive intermediate implicated in benzene toxicity. Peroxidases have been proposed to mediate the oxidation of p-hydroquinone to 1,4-benzoquinone. The Zymbal gland, nasal and oral cavities, mammary gland, and bone marrow all were found to possess greater peroxidase activity than contrasting nontarget tissues did. The metabolic capabilities of target tissues, including the ability to hydrolyze sulfate conjugates to free phenolic compounds, to oxidize benzene to phenolic metabolites, to bioactivate hydroquinone to a reactive intermediate, and to carry out peroxidative reactions may offer possible explanations for the greater susceptibility of these sites to benzene-induced tumorigenicity. Transport of sulfate conjugates and their release via hydrolysis (e.g., through sulfatase action) (“sulfate shunting”) and subsequent oxidation (e.g., through peroxidase action) may represent a novel mechanistic pathway by which potentially reactive benzene metabolites can gain access to target sites and initiate critical genotoxic events.

Odorant metabolism catalyzed by olfactory mucosal enzymes influences peripheral olfactory responses in rats

A large set of xenobiotic-metabolizing enzymes (XMEs), such as the cytochrome P450 monooxygenases (CYPs), esterases and transferases, are highly expressed in mammalian olfactory mucosa (OM). These enzymes are known to catalyze the biotransformation of exogenous compounds to facilitate elimination. However, the functions of these enzymes in the olfactory epithelium are not clearly understood. In addition to protecting against inhaled toxic compounds, these enzymes could also metabolize odorant molecules, and thus modify their stimulating properties or inactivate them. In the present study, we investigated the in vitro biotransformation of odorant molecules in the rat OM and assessed the impact of this metabolism on peripheral olfactory responses. Rat OM was found to efficiently metabolize quinoline, coumarin and isoamyl acetate. Quinoline and coumarin are metabolized by CYPs whereas isoamyl acetate is hydrolyzed by carboxylesterases. Electro-olfactogram (EOG) recordings revealed that the hydroxylated metabolites derived from these odorants elicited lower olfactory response amplitudes than the parent molecules. We also observed that glucurono-conjugated derivatives induced no olfactory signal. Furthermore, we demonstrated that the local application of a CYP inhibitor on rat olfactory epithelium increased EOG responses elicited by quinoline and coumarin. Similarly, the application of a carboxylesterase inhibitor increased the EOG response elicited by isoamyl acetate. This increase in EOG amplitude provoked by XME inhibitors is likely due to enhanced olfactory sensory neuron activation in response to odorant accumulation. Taken together, these findings strongly suggest that biotransformation of odorant molecules by enzymes localized to the olfactory mucosa may change the odorant’s stimulating properties and may facilitate the clearance of odorants to avoid receptor saturation.

Use of nasal cells in micronucleus assays and other genotoxicity studies

Genotoxicity experiments with exfoliated nasal mucosa cells are a promising minimally invasive approach for the detection of DNA-damaging compounds in ambient air. Results of single cell gel electrophoresis (SCGE) assays with individual cells and organ cultures from bioptic material show that DNA damage caused by compounds such as nitrosamines, polycyclic aromatic hydrocarbons and pesticides can be detected. Biochemical studies indicate that enzymes involved in the metabolism of environmental mutagens are represented in nasal cells. Several protocols for experiments with nasal cells have been developed and it was shown that formaldehyde, metals, styrene and crystalline silica induce DNA damage in SCGE and/or in micronucleus studies; furthermore, it was also found that polluted urban air causes DNA instability in nasal epithelial cells. Comparisons of these data with results obtained in lymphocytes and buccal cells indicate that nasal cells are in general equally sensitive. Broad variations in the baseline levels, differences of results obtained in various studies as well as the lack of information concerning the impact of confounding factors on the outcome of experiments with these cells indicate the need for further standardisation of the experimental protocols.

Effects of typical inducers on olfactory xenobiotic-metabolizing enzyme, transporter, and transcription factor expression in rats

Several xenobiotic-metabolizing enzymes (XMEs) have been identified in the olfactory mucosa (OM) of mammals. However, the molecular mechanisms underlying the regulation of these enzymes have been little explored. In particular, information on the expression of the transcriptional factors in this tissue is quite limited. The aim of the present study was to examine the impact of five typical inducers, Aroclor 1254, 3-methylcholanthrene, dexamethasone, phenobarbital, and ethoxyquin, on the activities and mRNA expression of several XMEs in the OM and in the liver of rats. We also evaluated the effects of these treatments on the mRNA expression of transcription factors and transporters. On the whole, the intensities of the effects were lower in the OM than in the liver. Dexamethasone was found to be the most efficient treatment in the OM. Dexamethasone induced the transcription of several olfactory phase I, II, and III genes [such as cytochromes P450 2A3 and 3A9, UDP-glucuronosyltransferase (UGT) 2A1, and multidrug resistance-related protein type 1] and increased UGT activities. We observed that dexamethasone up-regulated sulfotransferase 1C1 expression in the OM but down-regulated it in the liver. Aroclor and ethoxyquin induced the gene expression of CYP1A and quinone reductase, respectively, in the OM. The transcription factors aryl hydrocarbon receptor, nuclear factor E2-related factor 2 (Nrf2), peroxisome proliferator-activated receptor α, pregnane X receptor, and glucocorticoid receptor were detected in the OM, but no constitutive androstane receptor expression was observed. Dexamethasone and Aroclor enhanced olfactory Nrf2 expression. These results demonstrate that olfactory XME can be modulated by chemicals and that the mechanisms involved in the regulation of these enzymes are tissue-specific.

UDP-glucuronosyltransferases (UGTs) in neuro-olfactory tissues: expression, regulation, and function

This work aims to review uridine diphosphate (UDP)-glucuronosyltransferase (UGT) expression and activities along different neuronal structures involved in the common physiological process of olfaction: olfactory epithelium, olfactory bulb, and olfactory cortex. For the first time, using high-throughput in situ hybridization data generated by the Allen Brain Atlas (ABA), we present quantitative analysis of spatial distribution of UGT genes in the mouse brain. The olfactory area is a central nervous system site with the highest expression of UGTs, including UGT isoforms not previously identified in the brain. Since there is evidence of the transfer of xenobiotics to the brain through the nasal pathway, circumventing the blood-brain barrier, olfactory UGTs doubtlessly share the common function of detoxification, but they are also involved in the metabolism and turnover of exogenous or endogenous compounds critical for physiological olfactory processing in these tissues. The function of olfactory UGTs will be discussed with a special focus on their participation in the perireceptor events involved in the modulation of olfactory perception.

Ethyl tertiary-butyl ether: a toxicological review

A number of oxygenated compounds (oxygenates) are available for use in gasoline to reduce vehicle exhaust emissions, reduce the aromatic compound content, and avoid the use of organo-lead compounds, while maintaining high octane numbers. Ethyl tertiary-butyl ether (ETBE) is one such compound. The current use of ETBE in gasoline or petrol is modest but increasing, with consequently similar trends in the potential for human exposure. Inhalation is the most likely mode of exposure, with about 30% of inhaled ETBE being retained by the lungs and distributed around the body. Following cessation of exposure, the blood concentration of ETBE falls rapidly, largely as a result of its metabolism to tertiary-butyl alcohol (TBA) and acetaldehyde. TBA may be further metabolized, first to 2-methyl-1,2-propanediol and then to 2-hydroxyisobutyrate, the two dominant metabolites found in urine of volunteers and rats. The rapid oxidation of acetaldehyde suggests that its blood concentration is unlikely to rise above normal as a result of human exposure to sources of ETBE. Single-dose toxicity tests show that ETBE has low toxicity and is essentially nonirritant to eyes and skin; it did not cause sensitization in a maximization test in guinea pigs. Neurological effects have been observed only at very high exposure concentrations. There is evidence for an effect of ETBE on the kidney of rats. Increases in kidney weight were seen in both sexes, but protein droplet accumulation (with alpha(2u)-globulin involvement) and sustained increases in cell proliferation occurred only in males. In liver, centrilobular necrosis was induced in mice, but not rats, after exposure by inhalation, although this lesion was reported in some rats exposed to very high oral doses of ETBE. The proportion of liver cells engaged in S-phase DNA synthesis was increased in mice of both sexes exposed by inhalation. ETBE has no specific effects on reproduction, development, or genetic material. Carcinogenicity studies have been conducted with ETBE, TBA, and ethanol (included in this review as an endogenous precursor of acetaldehyde in the absence of TBA). A single experiment with ETBE in rats and several experiments with ethanol in rats and mice were not considered adequate for an evaluation of ETBE carcinogenicity. In male rats only, TBA induced alpha(2u)-globulin nephropathy-related renal tubule adenomas. These are generally considered to have no human relevance. In addition, increases in thyroid follicular cell adenoma incidence were associated with TBA treatment in female mice. This result lacks independent confirmation and is not supported by experiments in which similar or higher internal doses of TBA were delivered.

Nasal cytotoxic and carcinogenic activities of systemically distributed organic chemicals

Toxicity and carcinogenicity in the mucosa of the nasal passages in rodents has been produced by a variety of organic chemicals which are systemically distributed. In this review, 14 such chemicals or classes were identified that produced rodent nasal cytotoxicity, but not carcinogenicity, and 11 were identified that produced nasal carcinogenicity. Most chemicals that affect the nasal mucosa were either concentrated in that tissue or readily activated there, or both. All chemicals with effects in the nasal mucosa that were DNA-reactive, were also carcinogenic, if adequately tested. None of the rodent nasal cytotoxins has been identified as a human systemic nasal toxin. This may reflect the lesser biotransformation activity of human nasal mucosa compared to rodent and the much lower levels of human exposures. None of the rodent carcinogens lacking DNA reactivity has been identified as a nasal carcinogen or other cancer hazard to humans. Some DNA-reactive rodent carcinogens that affect the nasal mucosa, as well as other tissues, have been associated with cancer at various sites in humans, but not the nasal cavity. Thus, findings in only the rodent nasal mucosa do not necessarily predict either a toxic or carcinogenic hazard to that tissue in humans.

Regulation of cytochrome P450 gene expression in the olfactory mucosa

The mammalian olfactory mucosa (OM) is unique among extrahepatic tissues in having high levels, and tissue-selective forms, of cytochrome P450 (CYP) enzymes. These enzymes may have important toxicological implications, as well as biological functions, in this chemosensory organ. In addition to a tissue-selective, abundant expression of CYP1A2, CYP2A, and CYP2G1, some of the OM CYPs are also known to have an early developmental expression, a resistance to xenobiotic inducers, and a lack of responsiveness to circadian rhythm. Efforts to fully characterize the regulation of CYP expression in the OM, and to identify the underlying mechanisms, are important for our understanding of the physiological functions and toxicological significance of these biotransformation enzymes, and may also shed unique light on the general mechanisms of CYP regulation. The aim of this mini-review is to provide a summary of current knowledge of the various modes of regulation of CYPs expressed in the OM, an update on our mechanistic studies on tissue-selective CYP expression, and a review of the literature on xenobiotic inducibility of OM CYPs. Our goal is to stimulate further studies in this exciting research area, which is of considerable importance, in view of the constant exposure of the human nasal tissues to inhaled, as well as systemically derived, chemicals, the prevalence of olfactory system damage in individuals with neurodegenerative diseases, and the current uncertainty in risk assessments for potential olfactory toxicants.

Nasal administration of opioids for pain management in adults

BACKGROUND

Nasal administration of opioids may be an alternative route to intravenous, subcutaneous, oral transmucosal, oral or rectal administration in some patients. Key features may be self-administration, combined with rapid onset of action. The aim of this paper is to evaluate the present base of knowledge on this topic.

METHODS

The review is based on human studies found in Medline or in the reference list of these papers. The physiology of the nasal mucosa and some pharmaceutical aspects of nasal administration are described. The design of each study is described, but not systematically evaluated.

RESULTS

Pharmacokinetic studies in volunteers are reported for fentanyl, alfentanil, sufentanil, butorphanol, oxycodone and buprenorphine. Mean times for achieving maximum serum concentrations vary from 5 to 50 min, while mean figures for bioavailability vary from 46 to 71%. Fentanyl, pethidine and butorphanol have been studied for postoperative pain. Mean onset times vary from 12 to 22 min and times to peak effect from 24 to 60 min. There is considerable interindividual variation in pharmacokinetics and clinical outcome. This may partly be due to lack of optimization of nasal formulations. Patient-controlled nasal analgesia is an effective alternative to intravenous PCA. Adverse effects are mainly those related to the opioids themselves, rather than to nasal administration. Some experience with nasal opioids in outpatients and for chronic pain has also been reported.

CONCLUSION

Nasal administration of opioids has promising features, but is still in its infancy. Adequately designed clinical studies are needed. Improvements of nasal sprayer devices and opioid formulations may improve clinical outcome.

Bioavailability and pharmacokinetics of lorazepam after intranasal, intravenous, and intramuscular administration

The purpose of this study was to evaluate the pharmacokinetic profile of intranasal lorazepam in comparison to currently established administration routes. Eleven healthy volunteers completed this randomized crossover study. On three occasions, each separated by a 1-week washout, subjects received a 2 mg dose of lorazepam via the intranasal, intravenous, or intramuscular route. Blood samples were collected serially from 0 to 36 hours. Noncompartmental methods were used to determine pharmacokinetic parameters. Lorazepam was well absorbed following intranasal administration with a mean (%CV) bioavailability of 77.7(11.1). Intranasal administration resulted in a faster absorption rate than intramuscular administration. Elimination profiles were comparable between all three routes. The concentration-time profile for intranasal delivery demonstrated evidence of a double peak in several subjects, suggesting partial oral absorption. Females were found to have significantly higher AUC values than males for all three delivery routes. Overall, this study demonstrated favorable pharmacokinetics of intranasal lorazepam in relation to standard administration methods. Intranasal delivery could provide an alternative, noninvasive delivery route for lorazepam.

The toxicity of styrene to the nasal epithelium of mice and rats: studies on the mode of action and relevance to humans

Inhaled styrene is known to be toxic to the nasal olfactory epithelium of both mice and rats, although mice are markedly more sensitive. In this study, the nasal tissues of mice exposed to 40 and 160 ppm styrene 6 h/day for 3 days had a number of degenerative changes including atrophy of the olfactory mucosa and loss of normal cellular organisation. Pretreatment of mice with 5-phenyl-1-pentyne, an inhibitor of both CYP2F2 and CYP2E1 completely prevented the development of a nasal lesion on exposure to styrene establishing that a metabolite of styrene, probably styrene oxide, is responsible for the observed nasal toxicity. Comparisons of the cytochrome P-450 mediated metabolism of styrene to its oxide, and subsequent metabolism of the oxide by epoxide hydrolases and glutathione S-transferases in nasal tissues in vitro, have provided an explanation for the increased sensitivity of the mouse to styrene. Whereas cytochrome P-450 metabolism of styrene is similar in rats and mice, the rat is able to metabolise styrene oxide at higher rates than the mouse thus rapidly detoxifying this electrophilic metabolite. Metabolism of styrene to its oxide could not be detected in human nasal tissues in vitro, but the same tissues did have epoxide hydrolase and glutathione S-transferase activities, and were able to metabolise styrene oxide efficiently, indicating that styrene is unlikely to be toxic to the human nasal epithelium.

Rat olfactory bulb and epithelium UDP-glucuronosyltransferase 2A1 (UGT2A1) expression: in situ mRNA localization and quantitative analysis

UDP-glucuronosyltransferases (UGTs) form a multigenic family of enzymes involved in the biotransformation and elimination of numerous endo- and xenobiotic compounds. Beside the diverse UGT isoforms present in the liver as well as in other tissues, the UGT2A1 isoform, also called olfactory UGT, was initially thought to be expressed in the nasal epithelium only. In this work, we demonstrate the UGT2A1 mRNA expression in the olfactory bulb, using in situ hybridization and quantitative reverse transcription-polymerase chain reaction (RT-PCR) techniques. Within the epithelium, UGT2A1 mRNA is mainly found in the sustentacular cells and to a lesser extent in Bowman's gland cells. Moreover, in situ hybrization staining reveals UGT2A1 mRNA expression in the olfactory sensory neuron nuclei. Neuronal localization of UGT2A1 mRNA within the olfactory bulb is mainly found in the deeper granular cells. The development of the quantitative multistandard RT-PCR method firstly required characterization of the mouse Ugt2A1 cDNA by rapid amplification of cDNA ends (RACE)-PCR. UGT2A1 mRNA levels appear quantitatively six-fold lower in the olfactory bulb than in the epithelium, in both the rat and mouse. The expression of UGT2A1 in the olfactory bulb, which directly connects the nasal epithelium to the brain, emphasizes the potential role of this enzyme in the protection of the brain against airborne hazardous chemicals.

Health risks associated with inhaled nasal toxicants

Health risks of inhaled nasal toxicants were reviewed with emphasis on chemically induced nasal lesions in humans, sensory irritation, olfactory and trigeminal nerve toxicity, nasal immunopathology and carcinogenesis, nasal responses to chemical mixtures, in vitro models, and nasal dosimetry- and metabolism-based extrapolation of nasal data in animals to humans. Conspicuous findings in humans are the effects of outdoor air pollution on the nasal mucosa, and tobacco smoking as a risk factor for sinonasal squamous cell carcinoma. Objective methods in humans to discriminate between sensory irritation and olfactory stimulation and between adaptation and habituation have been introduced successfully, providing more relevant information than sensory irritation studies in animals. Against the background of chemoperception as a dominant window of the brain on the outside world, nasal neurotoxicology is rapidly developing, focusing on olfactory and trigeminal nerve toxicity. Better insight in the processes underlying neurogenic inflammation may increase our knowledge of the causes of the various chemical sensitivity syndromes. Nasal immunotoxicology is extremely complex, which is mainly due to the pivotal role of nasal lymphoid tissue in the defense of the middle ear, eye, and oral cavity against antigenic substances, and the important function of the nasal passages in brain drainage in rats. The crucial role of tissue damage and reactive epithelial hyperproliferation in nasal carcinogenesis has become overwhelmingly clear as demonstrated by the recently developed biologically based model for predicting formaldehyde nasal cancer risk in humans. The evidence of carcinogenicity of inhaled complex mixtures in experimental animals is very limited, while there is ample evidence that occupational exposure to mixtures such as wood, leather, or textile dust or chromium- and nickel-containing materials is associated with increased risk of nasal cancer. It is remarkable that these mixtures are aerosols, suggesting that their "particulate nature" may be a major factor in their potential to induce nasal cancer. Studies in rats have been conducted with defined mixtures of nasal irritants such as aldehydes, using a model for competitive agonism to predict the outcome of such mixed exposures. When exposure levels in a mixture of nasal cytotoxicants were equal to or below the "No-Observed-Adverse-Effect-Levels" (NOAELs) of the individual chemicals, neither additivity nor potentiation was found, indicating that the NOAEL of the "most risky chemical" in the mixture would also be the NOAEL of the mixture. In vitro models are increasingly being used to study mechanisms of nasal toxicity. However, considering the complexity of the nasal cavity and the many factors that contribute to nasal toxicity, it is unlikely that in vitro experiments ever will be substitutes for in vivo inhalation studies. It is widely recognized that a strategic approach should be available for the interpretation of nasal effects in experimental animals with regard to potential human health risk. Mapping of nasal lesions combined with airflow-driven dosimetry and knowledge about local metabolism is a solid basis for extrapolation of animal data to humans. However, more research is needed to better understand factors that determine the susceptibility of human and animal tissues to nasal toxicants, in particular nasal carcinogens.

Kinetics of propylene oxide metabolism in microsomes and cytosol of different organs from mouse, rat, and humans

Kinetics of the metabolic inactivation of 1,2-epoxypropane (propylene oxide; PO) catalyzed by glutathione S-transferase (GST) and by epoxide hydrolase (EH) were investigated at 37 degrees C in cytosol and microsomes of liver and lung of B6C3F1 mice, F344 rats, and humans and of respiratory and olfactory nasal mucosa of F344 rats. In all of these tissues, GST and EH activities were detected. GST activity for PO was found in cytosolic fractions exclusively. EH activity for PO could be determined only in microsomes, with the exception of human livers where some cytosolic activity also occurred, representing 1-3% of the corresponding GST activity. For GST, the ratio of the maximum metabolic rate (V(max)) to the apparent Michaelis constant (K(m)) could be quantified for all tissues. In liver and lung, these ratios ranged from 12 (human liver) to 106 microl/min/mg protein (mouse lung). Corresponding values for EH ranged from 4.4 (mouse liver) to 46 (human lung). The lowest V(max) value for EH was found in mouse lung (7.1 nmol/min/mg protein); the highest was found in human liver (80 nmol/min/mg protein). K(m) values for EH-mediated PO hydrolysis in liver and lung ranged from 0.83 (human lung) to 3.7 mmol/L (mouse liver). With respect to liver and lung, the highest V(max)/K(m) ratios were obtained for GST in mouse and for EH in human tissues. GST activities were higher in lung than in liver of mouse and human and were alike in both rat tissues. Species-specific EH activities in lung were similar to those in liver. In rat nasal mucosa, GST and EH activities were much higher than in rat liver.

Xenobiotic-metabolizing enzymes in pig nasal and hepatic tissues

1. A study of xenobiotic-metabolizing enzyme activity of the olfactory and respiratory epithelium in the pig was undertaken. The results indicated that porcine olfactory mucosa contains all the components of the P450 system. 2. Monooxygenase activities were much higher in olfactory than in respiratory microsomes, and the olfactory activities dependent on CYP2A were higher than those in the liver. By contrast, the olfactory monooxygenases associated with CYP2E1 were poorly or not detected, whereas CYP2G1 and a protein immunorelated to CYP1A2 were expressed in the olfactory epithelium. 3. The activities of several non oxidative enzymes (glutathione S-transferase, UDP-glucuronyl transferase, epoxide hydrolase, DT-diaphorase, benzaldehyde and propionaldehyde dehydrogenases, and various esterases) were also determined in porcine tissues and were found to be higher in the olfactory than in the respiratory mucosa, but lower or similar to those in liver. 4. An unexpected finding was a higher activity of olfactory UDP-GT compared with that of liver when 1-naphtol but not p-hydroxybiphenyl (a good substrate for a specific olfactory UDP-GT(olf) in bovine and rat) was used as substrate, suggesting a porcine specific expression of UDP-GT isoforms. 5. The results taken together indicate that the olfactory epithelium of mammals has a similar cytochrome P450 profile with the CYP2A and CYP2G1 as dominant isoforms, whereas the olfactory non-oxidative enzymes appear qualitatively and quantitatively expressed to different extents.

Metabolic capacity of nasal tissue interspecies comparisons of xenobiotic-metabolizing enzymes

High levels of xenobiotic-metabolizing enzymes occur in the nasal mucosa of all species studied. In certain species, including rats and rabbits, unique enzymes are present in the nasal mucosa. The function of these enzymes is not well understood, but it is thought that they play a role in protecting the lungs from toxicity of inhalants. The observation that several nasal xenobiotic-metabolizing enzymes accept odorants as substrates may indicate that these enzymes also play a role in the olfactory process. Xenobiotic-metabolizing enzymes were found in the nasal cavity around 15 years ago. Since that time, much has been learned about the nature of the enzymes and the substrates they accept. In the present review, this information is summarized with special attention to species differences in xenobiotic-metabolizing enzymes of the nasal cavity. Such differences may be important in interpreting the results of toxicity assays in animals because rodents are apparently more susceptible to nasal toxicity after exposure to inhalants than are humans.

Evaluation of hexamethylphosphoramide for gene mutations in Salmonella typhimurium using plate incorporation, preincubation, and suspension assays

Hexamethylphosphoramide (HMPA), a potent rat nasal carcinogen by inhalation, and three of its metabolites, pentamethylphosphoramide (PMPA), trimethylphosphoramide (TriMPA), and formaldehyde (HCHO), were assessed in Salmonella typhimurium gene mutation assays using various protocols, including plate incorporation, preincubation and suspension assays. HMPA (tested up to 15,000 micrograms/plate) was not mutagenic in plate incorporation or preincubation assays with or without metabolic activation. HCHO was mutagenic in the plate incorporation and preincubation assays (tested up to 150 micrograms/plate). In suspension assays, however, HMPA (tested up to 40 mg/ml), PMPA (up to 44 mg/ml) and HCHO (up to 45 micrograms/ml), but not TriMPA (up to 29 mg/ml), were mutagenic. HMPA and PMPA were positive only with activation. HMPA's mutagenicity was optimized using a relatively high level of rat liver S9 protein (3.5 mg/plate) in the metabolic activation mixture. Semicarbazide, an HCHO trapping agent, added at concentrations up to 167 micrograms/ml, markedly inhibited the mutagenic activities of HMPA and PMPA suggesting that HCHO generation may play a role in their mutagenicity. These studies show that HMPA is mutagenic in a modified Salmonella typhimurium reverse mutation assay with metabolic activation. Successive N-demethylation of HMPA eventually eliminates the mutagenic activity which further suggests that HMPA's mutagenic activity is related to the release of HCHO.

Metabolism-dependent activation and toxicity of chemicals in nasal glands

The mucosae of the nasal passages contain a large amount of glands which express secretory proteins as well as phase I and phase II biotransformation enzymes. In this review the metabolic activation, covalent binding and toxicity of chemicals in the Bowman's glands in the olfactory mucosa, in the sero-mucous glands in the nasal septum and in the lateral nasal glands and maxillary glands around the maxillary sinuses are discussed. Light microscopic autoradiographic studies have demonstrated a selective covalent binding of nasal toxicants and carcinogens such as halogenated hydrocarbons and N-nitrosamines, especially in the Bowman's glands following a single systemic exposure, suggesting a high rate of metabolic activation of chemicals in these glands. Special attention is put on the herbicide dichlobenil which induces necrosis in the olfactory mucosa following a cytochrome-P450-mediated metabolic activation and covalent binding in the Bowman's glands.

Purification and characterization of three constitutive cytochrome P-450 isoforms from bovine olfactory epithelium

Three constitutive forms of cytochrome P-450 (P-450s) were isolated from olfactory microsomes of cattle. The purified P-450s, designated P-450bov1, P-450bov2 and P-450bov3, were electrophoretically nearly homogeneous by SDS/PAGE and their apparent relative molecular masses were estimated to be 50000, 53000 and 51000 respectively. As indicated by several criteria including the N-terminal sequence and absorption spectra, the three olfactory forms of P-450 were distinct from each other and from all the other P-450s currently known in cattle. P-450bov1 and P-450bov2 were purified in the low-spin state, whereas P-450bov3 was in the high-spin state. Studies to evaluate, by Western blot analysis, the reactivity of these purified P-450s with antibodies raised against rat hepatic P-450 2E1, 2B, 1A and 3A and rabbit olfactory P-450NMa and P-450NMb showed that P-450bov3 strongly cross-reacted with anti-P-450NMb IgG, and P-450bov1 moderately with anti-P-450NMa IgG. As determined by immunoblots, P-450bov1 and P-450bov3 represented a great portion of the total olfactory P-450. In a reconstituted system with NADPH:cytochrome P-450 reductase and phospholipids, P-450bov1 was more active in the metabolism of xenobiotic compounds (i.e. O-de-ethylation of ethoxycoumarin and N-demethylation of hexamethylphosphoramide) than towards endogenous substrates (testosterone and progesterone). Conversely, P-450bov3 metabolized the xenobiotics at lower rates but exhibited total oxidation rates of the above sex hormones higher than those of P-450bov1. From the comparison of the catalytic, immunochemical and structural properties, it was inferred that P-450bov1 and P-450bov3 are the bovine orthologues of P-450NMa (2A) and P-450NMb (2G1) respectively, the only two olfactory P-450s previously purified from rabbit. P-450bov2, which showed low activity toward some exogenous and endogenous compounds, represents a novel purified olfactory hemoprotein possibly belonging to the 3A subfamily. These results are consistent with a specific presence of catalytically and structurally similar P-450s, at least for the major ones, in the olfactory mucosa of mammals.

Perireceptor events in olfaction

Before reaching olfactory receptor neurons, odorant molecules have to cross an aqueous interface: the nasal mucus in vertebrates and the sensillar lymph in insects. Biochemical interactions taking place between odorants and the elements of these phases are called perireceptor events. Main protein constituents of these media, in both insects and vertebrates, are OBPs (odorant-binding proteins). Another class of proteins active in the olfactory perireceptor area includes odorant-degrading enzymes. The structure and the properties of these major proteins, with particular reference to OBPs, are reviewed and their role in olfactory transduction is discussed.

Cytochrome P450 2A of nasal epithelium: regulation and role in carcinogen metabolism

In this study, we found that rat nasal coumarin-7-hydroxylase (COH) activity was two orders of magnitude higher than rat hepatic COH activity and could be induced by adding coumarin to the rats' drinking water. In western blot analysis, an anti-cytochrome P450 (Cyp) 2a-5 (mouse liver COH) antibody recognized a sharp band in the microsomal fraction of rat nasal epithelium but not of the liver; the band comigrated with Cyp2a-5. The intensity of the band was increased by the coumarin treatment. Similarly, in northern blot analysis, a cDNA probe specific for Cyp2a-5 recognized an mRNA in the nasal epithelium having the same size as mouse liver Cyp2a-5 mRNA; however, no hybridizable mRNA was recognized in liver preparations. Unlike the protein level, the level of the mRNA was not increased by coumarin. When northern blot analyses were performed with two oligoprobes specific for rat lung CYP2A3, an mRNA of similar size to Cyp2a-5 mRNA was recognized. In immunoinhibition analysis, anti-Cyp2a-5 antibody inhibited rat nasal COH activity and aflatoxin B1 (AFB1) metabolism completely. It inhibited N-nitrosodiethylamine (NDEA) and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) metabolism by 80-90%. In contrast, the hepatic metabolism of the four compounds was not affected by the antibody. When coumarin instead of anti-Cyp2a-5 antibody was used, a strong but variable inhibition of the nasal metabolism of AFB1, NDEA, and NNK was seen. The results suggest that an enzyme or enzymes similar to mouse liver Cyp2a-5, one of which may be CYP2A3, is expressed at high levels in rat nasal epithelium but not in the liver and that its expression is increased by coumarin, an odorant and a substrate of Cyp2a-5. The increase probably occurs by protein stabilization or stimulation of translation. The results also show that the enzyme has a key role in the nasal metabolism of three well-known carcinogens, AFB1, NDEA, and NNK and may therefore be an important contributing factor in nasal carcinogenesis.

Involvement of cytochrome P450 2E1-like isoform in the activation of N-nitrosobis(2-oxopropyl)amine in the rat nasal mucosa

Induction of tumours in the nasal olfactory region of MRC rats by N-nitrosobis(2-oxopropyl)amine (BOP) is inhibited by orchiectomy and restored by testosterone. These results suggest the involvement of a sex-specific enzyme in BOP bioactivation in rat nasal mucosa. The present study was undertaken to identify this enzyme. Enzyme-linked immunosorbent assay (ELISA) and the metabolism of known substrates (p-nitrophenol) pointed to a microsomal cytochrome P450 (P450) 2E1-like isoform as a candidate enzyme. A correlation was found between the enzyme activity in nasal mucosal microsomes and serum testosterone levels. Four times more activity was detected in the nasal mucosa than in the liver of male rats. Vanillin inhibited the activity of the nasal mucosal enzyme to a greater extent than that of the liver enzyme. The overall results suggest that a nasal mucosal P450 2E1-like isoform is involved in BOP metabolism.

Odorant-binding proteins

Odorant-binding proteins (OBPs) are low-molecular-weight soluble proteins highly concentrated in the nasal mucus of vertebrates and in the sensillar lymph of insects. Their affinity toward odors and pheromones suggests a role in olfactory perception, but their physiological function has not been clearly defined. Several members of this class of proteins have been isolated and characterized both in insects and vertebrates; in most species two or three types of OBPs are expressed in the nasal area. Vertebrates OBPs show significant sequence similarity with a superfamily of soluble carrier proteins called lipocalins. They include some proteins of particular interest that are thought to be involved in the mechanism of releasing and modulating chemical messages with pheromonal activity. The data on vertebrate OBPs are here reviewed together with the most relevant information on related proteins. Theories and models of the physiological functions of odorant-binding proteins are presented and discussed.

Acetone-dependent regulation of cytochromes P4502E1 and P4502B1 in rat nasal mucosa

The inducibility and molecular regulation of cytochrome P4502E1 (CYP2E1) has been examined in nasal mucosa of rats after acetone treatment and compared to that of cytochrome P4502B1 (CYP2B1). Twenty-four hours following treatment with acetone (5 mL/kg) for 2 days, the amount of CYP2E1 as well as the rate of microsomal 4-nitrophenol hydroxylase activity had increased by a factor of 2-3, in microsomes isolated from nasal mucosa. The increase in CYP2E1 was accompanied by a corresponding increase of CYP2E1 mRNA, as determined by northern and slot blot analyses. In contrast, hepatic and renal CYP2E1 mRNA, studied in the same rats, did not increase, despite the fact that the amount of CYP2E1 was increased 3- and 5-fold, respectively. The amount of CYP2B1, an isozyme known as acetone-inducible in other tissues, decreased significantly by acetone, as detected by immunoblot analysis. After 48 hr, the amount of CYP2E1 enzyme, the level of CYP2E1 mRNA and the rate of 4-nitrophenol hydroxylase activity had returned to normal levels, whereas in liver and kidneys the immunoreactive protein remained 3-4-fold higher than control. The results indicate that acetone does not regulate CYP2E1 in nasal mucosa by post-translational mechanisms, in contrast to the situation observed in liver and kidneys. This indicates a tissue-specific expression of post-translational regulatory systems responsible for P450 stabilization. Furthermore, nasal CYP2B1 also seems to be regulated in a tissue-specific manner by acetone.

Glutathione S-transferases in rat olfactory epithelium: purification, molecular properties and odorant biotransformation

The olfactory epithelium is exposed to a variety of xenobiotic chemicals, including odorants and airborne toxic compounds. Recently, two novel, highly abundant, olfactory-specific biotransformation enzymes have been identified: cytochrome P-450olf1 and olfactory UDP-glucuronosyltransferase (UGT(olf)). The latter is a phase II biotransformation enzyme which catalyses the glucuronidation of alcohols, thiols, amines and carboxylic acids. Such covalent modification, which markedly affects lipid solubility and agonist potency, may be particularly important in the rapid termination of odorant signals. We report here the identification and characterization of a second olfactory phase II biotransformation enzyme, a glutathione S-transferase (GST). The olfactory epithelial cytosol shows the highest GST activity among the extrahepatic tissues examined. Significantly, olfactory epithelium had an activity 4-7 times higher than in other airway tissues, suggesting a role for this enzyme in chemoreception. The olfactory GST has been affinity-purified to homogeneity, and shown by h.p.l.c. and N-terminal amino acid sequencing to constitute mainly the Yb1 and Yb2 subunits, different from most other tissues that have mixtures of more enzyme classes. The identity of the olfactory enzymes was confirmed by PCR cloning and restriction enzyme analysis. Most importantly, the olfactory GSTs were found to catalyse glutathione conjugation of several odorant classes, including many unsaturated aldehydes and ketones, as well as epoxides. Together with UGT(olf), olfactory GST provides the necessary broad coverage of covalent modification capacity, which may be crucial for the acuity of the olfactory process.

Drug-metabolizing enzymes in respiratory nasal mucosa and liver of cynomolgus monkey

1. Microsomal and cytosolic drug-metabolizing enzyme activities of respiratory mucosa of male and female monkeys have been determined and compared to those of monkey liver. The results demonstrated that cytochrome P-450, NADPH-cytochrome P-450 reductase and some monooxygenase activities, especially ethoxycoumarin O-deethylase activity, were present in respiratory epithelium, although at lower levels than in liver. 2. Activities of non-oxidative enzymes--namely, epoxide hydrolase, UDP-glucuronyltransferase, glutathione S-transferase, DT-diaphorase, carbonyl reductase, benzaldehyde and propionaldehyde dehydrogenases--were also detected in respiratory tissue, some at higher levels than in liver. 3. The enzymic activities found in monkey nasal mucosa are not very similar to those in corresponding human tissue where, for example, UDP-glucuronyltransferase activity is not detectable. This indicates that monkey is not necessarily the best animal model for studies of the human upper respiratory tract.

The accumulation and metabolism of 3-trifluoromethylpyridine by rat olfactory and hepatic tissues

The accumulation of [methyl-14C]3-trifluoromethylpyridine (14C-3-FMP) by rat olfactory and hepatic tissue in vivo and in vitro has been investigated. 14C-3-FMP accumulates rapidly and selectively in both tissues in vivo, with an appreciable proportion of this activity being associated with the protein macromolecular fractions. Similar results were seen when isolated tissues were incubated in vitro in the presence of 14C-3-FMP. Studies with a range of metabolic inhibitors demonstrated that accumulation into olfactory tissue in vitro was virtually abolished by metyrapone and SKF-525A, indicating a key role of cytochrome P-450 mediated metabolism in this process. This was substantiated further by the in vivo inhibition of accumulation by metyrapone. Studies on the in vitro metabolism of 14C-3-FMP by isolated rat olfactory tissue demonstrated the major metabolite to be 3-trifluoromethylpyridine-N-oxide (3-FMP N-oxide) which is known to cause olfactory and hepatic toxicity in the rat. Metyrapone, while inhibiting accumulation of radioactivity derived from both 14C-3-FMP and 14C-3-FMP N-oxide in this tissue in vitro, only inhibited the synthesis of this metabolite by approximately 60%, indicating that several metabolic stages are involved in the metabolism and accumulation of 14C-3-FMP.

Distribution of cytochrome P-450 monoxygenase enzymes in the nasal mucosa of hamster and rat

Deposition of inhaled particulates onto the respiratory mucosa is relatively great in that portion of the nasal cavity unprotected by ciliated, goblet, or keratinized superficial cells. The cytochrome P-450 system is an important enzyme system involved in the biotransformation of xenobiotics into metabolites that are more readily absorbed. To examine the transitional region caudal to the nasal vestibule, nasal tissues of hamster and rat were prepared for immunocytochemistry. Blocks of tissue representing four levels along the long axis of the nasal cavity were examined. Paraffin sections were processed through the avidin-biotin peroxidase procedure, with diaminobenzidine tetrahydrochloride as the chromagen. Enzyme localization was accomplished through the use of antibodies for three rabbit cytochrome P-450 isozymes; 2, 5, and 6 (subfamilies IIB, IVB, and IA, respectively); and for rabbit NADPH-cytochrome P-450 reductase. Enzyme distribution was similar in both hamster and rat nasal tissues except in cells of striated and intercalated ducts of nasal glands and in cells of the nasolacrimal duct where immunoreactivity was greater in the hamster. Immunoreactivity for reductase and isozyme 2 was intense in nonciliated cells lining the nonolfactory epithelium, in sustentacular cells of the olfactory epithelium, and in acinar cells of olfactory glands. Distribution of reaction products to isozyme 5 and 6 were similar to but not so intense as those of reductase and isozyme 2. Reaction products for reductase and isozyme 2 occurred generally in the same cellular and intracellular regions with the following exceptions: isozyme 2 was more concentrated in cells of striated ducts and of the nasolacrimal duct, and reductase was more abundant in intercalated ducts of nasal glands.(ABSTRACT TRUNCATED AT 250 WORDS)

Xenobiotic-metabolizing enzymes in human respiratory nasal mucosa

Study of oxidative and non-oxidative xenobiotic-metabolizing enzymes was undertaken in microsomal and cytosolic fractions of two human livers, 10 individual and several pooled samples of human respiratory nasal mucosa obtained by surgical operation of male and female patients affected by hypertrophy of the inferior turbinates. The purity of nasal microsomes was checked by electron microscopy and marker enzyme assay. The pooled samples of respiratory nasal epithelium contained, relative to liver, a low amount of cytochrome P450 (about 25 pmol/mg protein) and associated biotransformation activities, and a low level of other components of the mixed-function oxidase system such as cytochrome b5, NADH and NADPH-cytochrome c reductase however the NADH-cytochrome b5 reductase activity was comparable to that of liver. The P450-dependent monooxygenase activities such as ethoxycoumarin O-deethylase, ethoxyresorufin O-deethylase and the dimethylnitrosamine N-demethylase were found in nearly all nasal microsomal specimens. The aniline hydroxylase and the aminopyrine or hexamethylphosphoramide N-demethylases were detected only in the pooled nasal samples. With regard to the non-oxidative enzymes, the activities of glutathione S-transferase, DT-diaphorase, epoxide hydrolase, UDP-glucuronyl-transferase, carbonyl reductase, benzaldehyde and propionaldehyde dehydrogenases, were investigated both in the individual and pooled nasal tissues and livers. These activities were similar in nasal and liver tissue, except for UDP-glucuronyltransferase which was not detected in nasal mucosa. The present findings demonstrate that the respiratory section of human nose contains a wide array of oxidative and non-oxidative enzymes, which could play a crucial role in the bioactivation or detoxication in situ of inhaled xenobiotics.

Drug-metabolizing enzymes in liver, olfactory, and respiratory epithelium of cattle

The drug-metabolizing enzymes of olfactory and respiratory epithelium of cattle were determined. The data of nasal tissues were compared to those of bovine liver. Both oxidative and nonoxidative enzyme activities were investigated. Many compounds including testosterone were used as substrates for the P450-dependent monooxygenase activities. The results demonstrated that the P450 content and all the activities assayed including reduced nicotinamide adenine dinucleotide phosphate (NADPH)-cytochrome P450 reductase were much higher in the olfactory than in the respiratory mucosa and for some activities (hexamethyl-phosphoramide and dimethylnitrosamine N-demethylase, aniline hydroxylase, and ethoxycoumarin O-deethylase) the values in the olfactory tissue were even markedly higher than those of liver. Also the activities of some nonoxidative enzymes such as glutathione S-transferase, uridine 5'-diphosphate (UDP)-glucuronyl-transferase, and epoxide hydrolase were higher in the olfactory than in the respiratory mucosa but lower than in liver. The results taken together suggest that the olfactory and respiratory epithelium of cattle, which contain in addition to a wide array of nonoxidative enzymes multiple forms of P450, can be useful and easily available tissues to study the biotransformation processes of odorants.

Nasal cavity enzymes involved in xenobiotic metabolism: effects on the toxicity of inhalants

A decade ago, the ability of nasal tissues to metabolize inhalants was only dimly suspected. Since then, the metabolic capacities of nasal cavity tissues has been extensively investigated in mammals, including man. Aldehyde dehydrogenases, cytochrome P-450-dependent monooxygenases, rhodanese, glutathione transferases, epoxide hydrolases, flavin-containing monooxygenases, and carboxyl esterases have all been reported to occur in substantial amounts in the nasal cavity. The contributions of these enzyme activities to the induction of toxic effects from inhalants such as benzo-a-pyrene, acetaminophen, formaldehyde, cocaine, dimethylnitrosamine, ferrocene, and 3-trifluoromethylpyridine have been the subject of dozens of reports. In addition, the influence of these enzyme activities on olfaction and their contribution to vapor uptake is beginning to receive attention from the research community. Research in the next decade promises to provide answers to the many still unanswered questions posed by the presence of the substantial xenobiotic metabolizing capacity of the nasal cavity.

Glutathione transferases in human nasal mucosa

Glutathione transferase (GST) was investigated with 1-chloro-2,4-dinitrobenzene as substrate in tissues specimens of human nasal mucosa. The average +/- (SD) of GST activity in the cytosol was 76.8 +/- 21 nmol/min/mg with a range of 47-113. Using affinity chromatography and isoelectric focusing, the isozymes of GST from human nasal mucosa have been purified and characterized. On the criteria of isoelectric point, substrate specificities, apparent subunit molecular weight, sensitivity to characteristic inhibitors and immunological properties the major GST purified (about 85% of total activity) can be identified as class pi GST. Although a limited amount of class alpha GST was expressed by human nasal mucosa, no class mu isoenzymes was noted. In addition, we have also identified a GST subunit that cannot be related to any of three major classes of human GST.