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.     

Induction of olfactory mucosal and liver metabolism of lidocaine by 2,3,7,8-tetrachlorodibenzo-p-dioxin

Formulation of drugs for administration via the nasal cavity is becoming increasingly common. It is of potential clinical relevance to determine whether intranasal drug administration itself, or exposure to other xenobiotics, can modulate the levels and/or activity of nasal mucosal metabolic enzymes, thereby affecting the metabolism and disposition of the drug. In these studies, we examined changes in several of the major metabolic enzymes in nasal epithelial tissues upon exposure to the environmental contaminant 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), as well as the impact of these changes on the metabolism of a model intranasally administered drug, lidocaine. Results of these studies show that TCDD can induce multiple metabolic enzymes in the olfactory mucosa and that the pattern of induction in the olfactory mucosa does not necessarily parallel that which occurs in the liver. Further, increases in enzyme levels noted by Western blot analysis were associated with increased activities of several nasal mucosal enzymes as well as with enhanced conversion of lidocaine to its major metabolite, monoethyl glycine xylidide (MEGX). These results demonstrate that environmental exposures can influence the levels and activity of nasal mucosal enzymes and impact the pharmacology of drugs administered via the nasal route.     

Retinoic acid biosynthetic activity and retinoid receptors in the olfactory mucosa of adult mice

Retinoids play important roles in the ontogenic development of the olfactory system in mammals, but their function in adult olfactory mucosa has not been explored. In the present study, the olfactory mucosal expression of nuclear retinoid receptors was examined in adult mice. Several retinoic acid receptor isotypes were identified in olfactory mucosa from adult C57BL/6 mice by RNA-PCR and DNA sequence analysis, including RARbeta, RXRalpha, RXRbeta, and RXRgamma. In addition, a previously unidentified mouse RXRbeta isoform containing a 12-nucleotide insertion in exon 7 was detected. Furthermore, in vitro metabolic studies demonstrated that olfactory mucosal cytosolic and microsomal preparations are active in the biosynthesis of retinoic acids from all-trans- and 9-cis-retinal. These results indicate that components of the retinoid signal transduction system are expressed in adult olfactory mucosa and may play important roles in gene regulation in this unique tissue where olfactory neuronal cells are continuously replaced.     

Carnosine Synthesis in Olfactory Tissue During Ontogeny: Effect of Exogenous β-Alanine

Carnosine has now been demonstrated by chemical analysis to be present in rat olfactory mucosa on day 16 of gestation. The tissue content of this dipeptide then increases progressively during fetal and postnatal life. Radioactive carnosine can be isolated from cultured embryonic rat olfactory mucosa incubated with [14C]beta-alanine as early as 13-14 days of gestation. The amount of incorporation also increases progressively with the initial age of the explant and with time in culture indicating in vitro maturation of the carnosine synthesis capability of olfactory tissue. To test whether the level of beta-alanine was limiting the synthesis of carnosine, we evaluated the effect of elevated beta-alanine levels on tissue carnosine content. Exogenous beta-alanine caused an increase in the tissue content of carnosine at several ages in vivo and in vitro. In adult animals this increase was observed in olfactory bulb, olfactory mucosa, and skeletal muscle. However, there was no associated alteration in carnosine synthetase activity. In addition, the different half-lives of carnosine in olfactory tissue and muscle seemed unaltered, arguing against any effect on degradative enzymes. Thus, tissue carnosine levels are regulated, at least in part, by substrate availability. The early appearance of carnosine synthetic capacity during prenatal development indicates that this enzyme activity should be a valuable aid in studying early events in olfactory neuron maturation.     

Localization of CYP4B1 in the rat nasal cavity and analysis of CYPs as secreted proteins

CYP4B1 is highly expressed in rat nasal respiratory mucosa, and to a lesser extent in olfactory mucosa. Examination of high-power photomicrographs suggests that CYP4B1 may be a secreted protein, based on the fact that immunoreactivity appears to be present in the lumens of ducts of Bowman's glands (rather than intracellular localization, as we observed with an antibody recognizing CYP2F4) and in secretory granules in respiratory mucosa. Furthermore, anti-CYP4B1 immunoreactivity is present on the surface of both respiratory and olfactory mucosa. We used SignalP 3.0 analysis to ascertain the likelihood that rat CYP4B1 is a secreted protein. While this analysis does not suggest that rat CYP4B1 is a secreted protein, several other cytochrome P450 enzymes were predicted to be secreted proteins. The observation that multiple human cytochrome P450s appear to be secreted proteins helps to explain the appearance of anti-cytochrome P450 antigens in cases of human autoimmune liver diseases.     

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.     

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.     

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.     

Effects of P450 inhibition and induction on the olfactory toxicity of β, β′-iminodipropionitrile (IDPN) in the rat

In addition to the neurotoxic effects of β, β′-iminodipropionitrile (IDPN) which have been previously reported by other investigators, the olfactory toxicity of this compound has recently been uncovered in this laboratory. Due to the apparently conflicting observations that the IDPN-induced lesion in the olfactory mucosa is very focal in nature (suggesting site-specific activation) and the observation by other investigators that the behavioral effects of IDPN appear to be due to the parent compound, we initiated studies into the possible role of the cytochrome P450 enzymes in the olfactory toxicity of IDPN. Immunohistochemical studies with antibodies raised against several different P450 isoforms revealed good correlation between IDPN-induced olfactory mucosal degeneration and the localization of a protein immunoreacting with an antibody to P450 2E1. Enzymatic studies revealed that there is approximately fivefold more ρ-nitrophenol hydroxylation activity in the olfactory mucosa than in the liver on a per milligram microsomal protein basis. Administration of 1% acetone in the drinking water increased the levels of olfactory mucosal 2E1, and the increase in enzyme levels corresponded to increased olfactory toxicity of IDPN; inhibition of P450 activities with either metyrapone or carbon tetrachloride eliminated or significantly decreased the olfactory toxicity of IDPN, respectively. These studies suggest a role for cytochrome P450, specifically the 2E1 isoform, in the activation of IDPN within the nasal mucosa.     

Alterations in the proteome of the respiratory tract in response to single and multiple exposures to naphthalene

Protein adduction is considered to be critical to the loss of cellular homeostasis associated with environmental chemicals undergoing metabolic activation. Despite considerable effort, our understanding of the key proteins mediating the pathologic consequences from protein modification by electrophiles is incomplete. This work focused on naphthalene (NA) induced acute injury of respiratory epithelial cells and tolerance which arises after multiple toxicant doses to define the initial cellular proteomic response and later protective actions related to tolerance. Airways and nasal olfactory epithelium from mice exposed to 15 ppm NA either for 4 h (acute) or for 4 h/day × 7 days (tolerant) were used for label‐free protein quantitation by LC/MS/MS. Cytochrome P450 2F2 and secretoglobin 1A1 are decreased dramatically in airways of mice exposed for 4 h, a finding consistent with the fact that CYPs are localized primarily in Clara cells. A number of heat shock proteins and protein disulfide isomerases, which had previously been identified as adduct targets for reactive metabolites from several lung toxicants, were upregulated in airways but not olfactory epithelium of tolerant mice. Protein targets that are upregulated in tolerance may be key players in the pathophysiology associated with reactive metabolite protein adduction. All MS data have been deposited in the ProteomeXchange with identifier PXD000846 ( http://proteomecentral.proteomexchange.org/dataset/PXD000846 ).     

The antiobesity effect of dehydroepiandrosterone in rats.

Initial studies showed that dehydroepiandrosterone (DHEA) treatment in mice resulted in lower body weight gain. Subsequent studies have shown that DHEA treatment in rats has a similar effect. In adult rodents, weight loss is a consequence of DHEA treatment. In general, these effects are independent of changes in food intake and are accompanied by lower body fat. DHEA treatment has been shown in some circumstances to alter a number of serum factors including glucose, insulin, cholesterol, and triacylglycerol. Recent studies have focused on the effects of DHEA on liver metabolism. Studies have been undertaken to determine whether the antiobesity effect of DHEA is mediated by the previously described inhibition of glucose-6-phosphate dehydrogenase by this steroid. It appears that inhibition of glucose-6-phosphate dehydrogenase in liver is not the initial metabolic response to DHEA but may play a contributing role. Inhibition of glucose-6-phosphate dehydrogenase in adipose tissue may affect differentiation of fat cells. A number of other enzymes involved in lipid and carbohydrate metabolism have also been shown to be altered by DHEA treatment, and several futile cycles involving some of these enzymes have been proposed to play a role in DHEA's antiobesity action. In addition, mitochondrial protein content is elevated by DHEA treatment. There appear to be time-dependent changes due to DHEA treatment on hepatic mitochondrial state three rates of respiration. Studies continue to evaluate the role of alterations in mitochondrial metabolism in DHEA's antiobesity action.     

Differential expression of Alpha,Mu, and Pi classes of glutathione S-transferases in chemosensory mucosae of rats during development

The expression of three classes of glutathione S-transferases (GSTs), Alpha, Mu, and Pi was investigated in the nasal mucosae of rats during development using immunohistochemical methods. GST Alpha and Mu were first detected in the supranuclear region of sustentacular cells on embryonic days 16. The Bowman's glands expressed differential patterns of immunoreactivity during development, beginning at postnatal day (P) 2 and P6 for Alpha and Mu classes, respectively and being greatest at P11 for both. The acinar cells of vomeronasal glands in the vomeronasal organ expressed Alpha and Mu classes of GSTs from P11 onwards. In the septal organ of Masera, the supranuclear region of sustentacular cells expressed GSTs from P11 with little or no variation during development. In the respiratory mucosa, Alpha and Mu classes of GSTs were detected at the brush borders of ciliated cells and in the acinar cells of posterior septal glands, but not in anterior septal or respiratory glands located on the turbinates. Compared to olfactory mucosa, the changes in immunoreactivity for GSTs were less pronounced in the respiratory mucosa during development. Specific GST Pi immunoreactivity was not detected in the nasal mucosae at any stage of development studied. The occurrence of GSTs in the nasal mucosa, including olfactory, vomeronasal, septal, and respiratory epithelia, suggests that the GSTs are actively involved in the biotransformation of xenobiotics including odorants and pheromones, and may also participate in perireceptor processes such as odorant clearance. In addition, we have developed a working model describing the cellular localization of certain phase I (e.g., cytochrome P-450s) and phase II (e.g., GSTs, -glutamyl transpeptidase) biotransformation enzymes in the olfactory mucosa and their proposed roles in xenobiotic metabolism.     

Immunolocalization of cytochromes P-450olf1 and P-450olf2 in rat olfactory mucosa

Previously, we described two olfactory-specific cytochromes P-450: rat cytochrome P-450olf1 (IIG1), identified by cDNA cloning, and bovine cytochrome P-450olf2 (IIA), identified by peptide microsequencing of a transmembranal polypeptide (p52). Here we describe the preparation of polyclonal antisera against peptide sequences of these proteins and their use in the immunolocalization of cytochromes P-450olf1 and P-450olf2 in rat olfactory mucosa. Immunoreactivities related to both enzymes are found in the subepithelial Bowman's glands of olfactory mucosa. Practically no immunoreactivity was found in other rat tissues, including liver, lung, kidney and respiratory mucosa. In addition, double-labeling experiments demonstrated that cytochromes P-450olf1 and P-450olf2 are present in the same population of Bowman's glands. The olfactory-specific localization of cytochromes P-450olf1 and P-450olf2 is consistent with a role for these enzymes in the modification or clearance of odorants from the chemosensory tissue.     

Degeneration and regeneration of olfactory cells induced by ZnSO4 and other chemicals

The necrotic effect of various salt solutions was tested on the catfish olfactory mucosa. Only zinc cations were able to induce an extensive degeneration of the olfactory cells. Two different modes of irrigation of the mucosa with zinc sulfate were investigated. (1) The olfactory cavity is flushed with the chemical for not more than a few seconds. At concentrations above 30 mM, the resulting damage is very reproducible, largely concentration independent and almost completely specific for the olfactory receptor cells. The non-sensory respiratory cells are unaffected, the sustentacular cells surrounding the receptor cells are affected mainly by a loss of microvilli. The olfactory receptor cells, on the contrary, start to degenerate within a few hours and by day 4 only 20% of the original receptor population remains. Division of the mucosal basal cells increases during days 3 and 4 on and day 6 olfactory receptor cells reach the bare surface of the lamella. After day 7, the receptor population reaches a level of more than 80% of its original value. Because of the absence of sustentacular processes covering the olfactory cell's knobs on day 6, it has been possible to confirm that each of the two types of olfactory receptor cells previously characterized are concentrated on each half of the mucosa. (2) The salt is maintained in contact with the tissue for several days. After this treatment most of the lamellae are irreversibly destroyed, some regeneration occurs in limited areas of the mucosa. In these small areas, indifferent respiratory cells reappear first between 20 and 35 days. It is only when the structure of the olfactory tissue is completely reorganized that the new receptor cells reappear between days 45 and 55. Regeneration is not completed before 60–65 days.     

Prevention of chemically induced changes in synaptosomal membrane order by ganglioside GM1 and alpha-tocopherol.

Synaptosomal membrane order has been studied by analysis of light depolarization by fluorescent dyes intercalated within membranes following exposure to various environmental toxicants. Two probes were explored: 1,6-diphenyl-1,3,5-hexatriene (DPH), signaling predominantly from the lipid-rich membrane core, and 1-[4-(trimethylamino)phenyl]-6-phenyl-1,3,5-hexatriene (TMA-DPH), reporting from the more hydrophilic membrane surface. Chlordecone, a neurotoxic insecticide, decreased the anisotropy of either dye and this change could be prevented by prior treatment of synaptosomes with ganglioside GM1 but not alpha-tocopherol. Exposure to an iron-ascorbic acid oxidizing mixture enhanced synaptosomal membrane order and this effect was blocked by preincubation with alpha-tocopherol but not ganglioside GM1. While these interactions may have partially reflected additive anisotropy changes, the protective agents were also effective at concentrations where they did not in themselves modulate membrane order. Methyl mercuric chloride at concentrations up to 100 microM had no discernable effect upon membrane order. It is suggested that these changes in membrane order may underlie some of the previously reported variations in the content of ionic calcium and in the leakiness of synaptosomes.     

Metabolic activation of the herbicide dichlobenil in the olfactory mucosa of mice and rats

The metabolic activation of the herbicide dichlobenil (2,6-dichloro[ring-14C]benzonitrile) in the olfactory mucosa of C57BL mice and Sprague-Dawley rats was examined. In homogenates of the olfactory mucosa (mouse 1000 x g supernatants; rat microsomes), dichlobenil was metabolized and covalently bound to protein. The apparent Km, Vmax and V/K values showed that the olfactory mucosa had both a higher affinity for dichlobenil and a higher capacity/mg protein to activate dichlobenil in comparison to the liver. The covalent binding was dependent on NADPH and was inhibited by the addition of dithionite, metyrapone and glutathione indicating an oxidative cytochrome P-450 dependent activation of dichlobenil into an electrophilic intermediate. The covalent binding was also inhibited by the addition of superoxide dismutase whereas catalase, mannitol or dimethylsulfoxide had no effect indicating the involvement of O2- but not of H2O2 or OH. in the activation. In explants of the olfactory mucosa incubated with [14C]dichlobenil a preferential covalent binding was observed in the Bowman's glands suggesting an activation of dichlobenil in these structures. The highly efficient metabolic activation of dichlobenil to reactive intermediates in the olfactory mucosa is suggested to be of importance for the potent dichlobenil-induced toxicity in this tissue.     

Histochemical studies on the distribution of some enzymes of the glycolytic pathways in the olfactory bulb of the squirrel monkey (Saimiri sciureus)

Summary Detailed histochemical studies on the distribution of glycolytic enzymes have been made in the olfactory bulb of the Squirrel Monkey. The olfactory glomeruli, mitral cells, tufted cells, glial cells and nerve fibers are well equipped with the enzymes of the glycolytic pathways. Granule cells do not have the ability to synthesize or breakdown glycogen, but they have the Embden-Meyerhof-Parnas pathway and the Warburg-Dickens pathway. The synapses of the olfactory glomeruli may have the ability to break-down glycogen for an energy source. Small glial cells found in the olfactory glomeruli may be a special type of oligodendrocyte. Glial cells found abundantly in and around the olfactory glomeruli may be energy donators to the synapses of the olfactory glomeruli. It is suggested that oligodendrocytes and astrocytes of the olfactory bulb may have different branching enzymes.Visiting scientist from Anatomy Department, Tokyo Medical and Dental University, Tokyo, Japan. T. R. Shanthaveerappa in previous publications.     

Cell-specific expression of CYP2A5 in the mouse respiratory tract: effects of olfactory toxicants.

We performed a detailed analysis of mouse cytochrome P450 2A5 (CYP2A5) expression by in situ hybridization (ISH) and immunohistochemistry (IHC) in the respiratory tissues of mice. The CYP2A5 mRNA and the corresponding protein co-localized at most sites and were predominantly detected in the olfactory region, with an expression in sustentacular cells, Bowman's gland, and duct cells. In the respiratory and transitional epithelium there was no or only weak expression. The nasolacrimal duct and the excretory ducts of nasal and salivary glands displayed expression, whereas no expression occurred in the acini. There was decreasing expression along the epithelial linings of the trachea and lower respiratory tract, whereas no expression occurred in the alveoli. The hepatic CYP2A5 inducers pyrazole and phenobarbital neither changed the CYP2A5 expression pattern nor damaged the olfactory mucosa. In contrast, the olfactory toxicants dichlobenil and methimazole induced characteristic changes. The damaged Bowman's glands displayed no expression, whereas the damaged epithelium expressed the enzyme. The CYP2A5 expression pattern is in accordance with previously reported localization of protein and DNA adducts and the toxicity of some CYP2A5 substrates. This suggests that CYP2A5 is an important determinant for the susceptibility of the nasal and respiratory epithelia to protoxicants and procarcinogens.     

Study of P450 function using gene knockout and transgenic mice

The xenobiotic-metabolizing P450s have been extensively studied for their ability to metabolize endogenous and exogenous chemicals. The latter include drugs and dietary and environmentally derived toxicants and carcinogens. These enzymes also metabolize endogenous steroids and fatty acids. P450s are thought to be required for efficient removal of most xenobiotics from the body and to be responsible for the hazardous effects of toxicants and carcinogens based on their ability to convert chemicals to electrophilic metabolites that can cause cellular damage and gene mutations. P450 catalytic activities have been extensively studied in vitro and in cell culture, yielding considerable information on their mechanisms of catalysis, substrate specificities, and metabolic products. Targeted gene disruption has been used to determine the roles of P450s in intact animals and their contributions to the mechanisms of toxicity and carcinogenesis. The P450s chosen for study, CYP1A1, CYP1B1, CYP1A2, and CYP2E1, are conserved in mammals and are known to metabolize most toxicants and chemical carcinogens. Mice lacking expression of these enzymes do not differ from wild-type mice, indicating that these P450s are not required for development and physiological homeostasis. However, the P450 null mice have altered responses to the toxic and carcinogenic effects of chemicals as compared with wild-type mice. These studies establish that P450s mediate the adverse effects of drugs and dietary, environmental, and industrial chemicals and serve to validate molecular epidemiology studies that seek to determine links between P450 polymorphisms and susceptibility to chemically associated diseases. More recently, P450 humanized mice have been produced.