Strontium90 for determination of time since death

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.

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Drug Targeting to the Brain: Transfer of Picolinic Acid Along the Olfactory Pathways

Bergström

Franzén

Eriksson

et al. 2002

Journal of Drug Targeting

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Picolinic acid (PA) protects against quinolinic acid- and kainic acid-induced neurotoxicity in the brain. To study the uptake of PA to the brain, we administered [3H]PA via a unilateral nasal instillation or iv injection to mice. Autoradiography demonstrated a rapid uptake of radioactivity in the olfactory nerve layer and in the ipsilateral olfactory bulb (OB) following nasal instillation of [3H]PA. After 4 h, there was a high level of radioactivity in the central parts of the ipsilateral OB and olfactory peduncle. Moreover, iv injection of [3H]PA demonstrated a selective uptake and retention of radioactivity in the OB. Gas chromatography-mass spectrometry (GC-MS) demonstrated the presence of PA and PA-glycine conjugate in the OB. In mice with reduced peripheral olfactory innervations there was a decreased uptake of [3H]PA in the OB as compared to controls suggesting that an intact olfactory neuroepithelium is a prerequisite for an uptake of PA to the OB. There is an increased interest in brain targeting of drugs with limited ability to pass the blood-brain barrier. The present results demonstrate that PA fulfils structural requirements for a transfer along the olfactory pathways to the brain.

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Transfer of Some Carboxylic Acids in the Olfactory System Following Intranasal Administration

Eriksson

Bergman

Franzén

et al. 1999

Journal of Drug Targeting

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The uptake of [14C]benzoic acid, 4-chloro[14C]benzoic acid, [3H]phthalic acid and [14C]salicylic acid in the nasal passages and brain was determined following a unilateral intranasal instillation in mice. An uptake of radioactivity from the nasal mucosa to the ipsilateral olfactory bulb was observed up to 4 h after administration following intranasal instillation of these carboxylic acids whereas the level was low in the contralateral olfactory bulb. Autoradiography of mice given [14C]benzoic acid and [14C]salicylic acid by intranasal instillation showed a preferential localization of radioactivity in the axonal and glomerular layer of the olfactory bulb 1 h after the administration. Four hours after administration the radioactivity was present as a gradient from the axonal layer towards the center of the olfactory bulb. Pretreatment of mice with a compound known to damage the olfactory neuroepithelium resulted in a decreased uptake of [14C]benzoic acid in the olfactory bulb. Thin layer chromatography of supernatants from the ipsilateral olfactory bulbs of mice given [14C]benzoic acid by nasal instillation indicated that the radioactivity in the bulbs represented unchanged compound. These results suggest that there is a transfer of some aromatic carboxylic acids in the olfactory pathways.

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Toxicant-induced ER-stress and caspase activation in the olfactory mucosa

Franzén

Brittebo

2005

Arch Toxicol

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The potent olfactory toxicant 2,6-dichlorophenyl methylsulphone (2,6-diClPh-MeSO(2)) induces rapid cell death and long-term metaplastic changes in the olfactory regions of rodents. The damage is related to a tissue-specific and extensive cytochrome P450 (CYP)-mediated metabolic activation of the compound to reactive intermediates. The aim of the present study was to examine the early, cell-specific changes leading to cell death in the olfactory mucosa of mice exposed to 2,6-diClPh-MeSO(2). We have examined the expression of the ER-specific stress protein GRP78, the presence of secretory glycoproteins, and the cellular activation of the initiator caspase 12 and the downstream effector caspase 3. 2,6-DiClPh-MeSO(2) induced rapid and cell-specific expression of GRP78, and activation of caspases 12 and 3 in the Bowman's glands. No similar early onset changes in the neuroepithelium were observed. Based on these results, we propose that extensive lesions are initiated in the Bowman's glands and that the metabolic activation of 2,6-diClPh-MeSO(2) elicits ER-stress response and subsequent apoptotic signaling at this site. Since most of the Bowman's glands had oncotic morphology, the results suggest that the terminal phase of apoptosis was blocked and that these glands finally succumb to other routes of cell death.

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Isomer-Specific Bioactivation and Toxicity of Dichlorophenyl Methylsulphone in Rat Olfactory Mucosa

Franzén¹,

Carlsson²,

Brandt³

et al. 2003

Toxicologic Pathology

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This study aimed to explain the isomer- and site-specific toxic effects of dichlorophenyl methylsulphone in the olfactory mucosa of rats. A single ip dose of the 2,6-chlorinated isomer (16 or 65 mg/kg) induced necrosis preferentially in the Bowman's glands and neuroepithelium in the dorsomedial part of the olfactory region. Only minor damage occurred at this site in rats dosed with the 2,5-chlorinated isomer (65 mg/kg). A strong concentration- and time-dependent covalent binding of the (14)C-labeled 2,6-isomer to rat olfactory microsomes was demonstrated. In contrast, no significant covalent binding of the (14)C-labeled 2,5-isomer was observed. The cytochrome P450 (CYP) inhibitors metyrapone, tranylcypromine and acetonitrile inhibited covalent binding of the 2,6-isomer to olfactory microsomes. Glutathione (GSH) appeared to play a protective role as a scavenger of a reactive intermediate whereas methyl-GSH did not alter covalent binding to olfactory microsomes. As determined by microautoradiography, binding of the 2,6-chlorinated isomer in the olfactory mucosa was confined to the Bowman's glands. Both isomers showed a low binding to liver microsomes and caused no liver injury. We suggest that a CYP2A-catalyzed activation of the 2,6-chlorinated dichlorophenyl methylsulphone to a reactive intermediate and adduct formation in the Bowman's glands will initiate a site-specific toxicity of this isomer in the olfactory mucosa.

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Anna Franzén

Cell-specific Expression of CYP2A5 in the Mouse Respiratory Tract: Effects of Olfactory Toxicants

Drug Targeting to the Brain: Transfer of Picolinic Acid Along the Olfactory Pathways

Transfer of Some Carboxylic Acids in the Olfactory System Following Intranasal Administration

Toxicant-induced ER-stress and caspase activation in the olfactory mucosa

Isomer-Specific Bioactivation and Toxicity of Dichlorophenyl Methylsulphone in Rat Olfactory Mucosa

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