Attenuation of histamine-induced airway effects by intranasal application of levocetirizine in mice.

The present study was performed to investigate the histamine-induced airway effect of levocetirizine, an active enantiomer of cetirizine, by intranasal application using ddY mice. Nasal rubbing and sneezing after histamine application into the nasal cavity were used as an index of histamine-induced airway effect in mice. Intranasal application of levocetirizine inhibited both nasal rubbing and sneezing concentration-dependently, and the ED50 values were 0.62 (0.51-0.77) and 0.70 (0.51-1.02) %/site for nasal rubbing and sneezing, respectively. ED50 values of cetirizine were 1.24 (1.02-1.59) and 1.35 (1.02-2.08) %/site for nasal rubbing and sneezing, respectively. Levocetirizine also inhibited nasal rubbing and sneezing when administered orally. These results clearly indicate that levocetirizine was about two times more potent than cetirizine by intranasal application, similar to the findings of the former's affinity for human histamine H1 receptors. In addition, the present findings raise the expectation of the development of levocetirizine nasal drops.

[The lipid metabolism abnormality in patients administered with olanzapine].

The atypical antipsychotic medication olanzapine is a useful agent in acute and maintenance treatment of schizophrenia and related disorders. It has beneficial effects on both positive and negative symptoms, an early onset of antipsychotic action and a favourable side effect profile. On the other hand, olanzapine has many reports of causing weight gain, glucose metabolism disturbances and lipidosis. We carried out blood tests (leptin, adiponectin, remnant-like lipoprotein cholesterol (RLP-C), total cholesterol, HbA1C, 75-OGTT and etc.) on patients with schizophrenia who had taken olanzapine. As a result, leptin, neutral lipid and RLP-C were significantly correlated by BMI. (The average blood test data and BMI revealed a normal range). Most analysis results of the lipoprotein fraction by a polyacrylamide-gel-electrophoresis method were normal patterns. Furthermore, the serum insulin concentrations from 75 g glucose tolerance (75 g-OGTT) 30 minutes later, in one third of patients receiving olanzapine, registered more than 100 microU/ml. The mechanism of the insulin secretion rise by olannzapine is unknown. Olanzapine may impair glucose tolerance due in part to increased insulin resistance. These findings do not necessarily imply that olanzapine is directly associated with a risk of impairment of weight gain, glucose metabolism disturbances and lipidosis. These results suggest that it is useful to promote diet cure and exercise therapy with patients with high BMI levels.

Trimethyltin initially activates the caspase 8/caspase 3 pathway for damaging the primary cultured cortical neurons derived from embryonic mice.

The organotin trimethyltin (TMT) is well known to cause neuronal damage in the central nervous system. To elucidate the mechanisms underlying the toxicity of TMT toward neurons, we prepared primary cultures of neurons from the neocortex of mouse embryos. A continuous exposure to TMT produced a decrease in cell viability as well as an increase in the number of cells with nuclear condensation/shrinkage at the exposure time window up to 24 hr. In addition to the events at the early time window, lactate dehydrogenase released was significantly elevated at the later exposure time from 36 to 48 hr. With a 3-hr exposure to TMT, a significant increase was observed in the activity of caspase 8, but not in that of caspase 9. TMT exposure produced no elevation in the level of cytochrome c released from mitochondria until 12 hr of exposure, with a significant facilitation of cytochrome c release at the exposure times of 16 and 24 hr. After the activation of caspase 8 by TMT exposure, caspase 3 activation and nuclear translocation of caspase-activated DNase were caused by exposure for 6 hr or longer. However, nuclear DNase II was elevated at the later time window of exposure. A caspase inhibitor completely prevented TMT from damaging the cells in any time window. Taken together, our data are the first demonstration that TMT toxicity is initially caused by activation of the caspase 8/caspase 3 pathway for nuclear translocation of DNases in cortical neurons in primary culture.

Altered expression of heat shock protein 110 family members in mouse hippocampal neurons following trimethyltin treatment in vivo and in vitro.

The heat shock protein (Hsp) 110 family is composed of HSP105, APG-1, and APG-2. As the response of these proteins to neuronal damage is not yet fully understood, in the present study, we assessed their expression in mouse hippocampal neurons following trimethyltin chloride (TMT) treatment in vivo and in vitro. Although each of these three Hsps had a distinct regional distribution within the hippocampus, a low level of all of them was observed in the granule cell layer of the dentate gyrus in naïve animals. TMT was effective in markedly increasing the level of these Hsps in the granule cell layer, at least 16h to 4days after the treatment. In the dentate granule cell layer on day 2 after TMT treatment, HSP105 was expressed mainly in the perikarya of NeuN-positive cells (intact neurons); whereas APG-1 and APG-2 were predominantly found in NeuN-negative cells (damaged neurons as evidenced by signs of cell shrinkage and condensation of chromatin). Assessments using primary cultures of mouse hippocampal neurons exposed to TMT revealed that whereas HSP105 was observed in intact neurons rather than in damaged neurons, APG-1 and APG-2 were detected in both damaged neurons and intact neurons. Taken together, our data suggest that APG-1 and APG-2 may play different roles from HSP105 in neurons damaged by TMT.

Enhanced expression of RNase L as a novel intracellular signal generated by NMDA receptors in mouse cortical neurons.

Recently we showed that the level of mitochondrial mRNA was decreased prior to neuronal death induced by glutamate. As the level of mRNA is regulated by ribonuclease (RNase), we examined RNase activity and its expression in the primary cultures of cortical neurons after glutamate treatment in order to evaluate the involvement of RNase in glutamate-induced neuronal death. A 15-min exposure of the cultures to glutamate at the concentration of 100 microM produced marked neuronal damage (more than 70% of total cells) at 24-h post-exposure. Under the experimental conditions used, RNA degradation was definitely observed at a period of 4-12-h post-exposure, a time when no damage was seen in the neurons. Glutamate-induced RNA degradation was completely prevented by the N-methyl-d-aspartic acid (NMDA) receptor channel blocker MK-801 or the NR2B-containing NMDA receptor antagonist ifenprodil. Glutamate exposure produced enhanced expression of RNase L at least 2-12h later, which was absolutely abolished by MK-801. However, no significant change was seen in the level of RNase H1 mRNA at any time point post-glutamate treatment. Immunocytochemical studies revealed that RNase L expressed in response to glutamate was localized within the nucleus, mitochondria, and cytoplasm in the neurons. Taken together, our data suggest that expression of RNase L is a signal generated by NMDA receptor in cortical neurons. RNase L expression and RNA degradation may be events that cause neuronal damage induced by NMDA receptor activation.

In vivo depletion of endogenous glutathione facilitates trimethyltin-induced neuronal damage in the dentate gyrus of mice by enhancing oxidative stress.

Acute treatment with trimethyltin chloride (TMT) produces neuronal damage in the hippocampal dentate gyrus of mice. We investigated the in vivo role of glutathione in mechanisms associated with TMT-induced neural cell damage in the hippocampus by examining mice depleted of endogenous glutathione by prior treatment with 2-cyclohexen-1-one (CHO). In the hippocampus of animals treated with CHO 1h beforehand, a significant increase was seen in the number of single-stranded DNA-positive cells in the dentate gyrus when determined on day 2 after the injection of TMT at a dose of 2.0 mg/kg. Immunoblot analysis revealed that CHO treatment induced a significant increase in the phosphorylation of c-Jun N-terminal kinase in the cytosolic and nuclear fractions obtained from the dentate gyrus at 16 h after the TMT injection. There was also a concomitant increase in the level of phospho-c-Jun in the cytosol at 16 h after the injection. Expectedly, lipid peroxidation was increased by TMT in the hippocampus, and was enhanced by the CHO treatment. Moreover, CHO treatment facilitated behavioral changes induced by TMT. Taken together, our data indicate that TMT-induced neuronal damage is caused by activation of cell death signals induced at least in part by oxidative stress. We conclude that endogenous glutathione protectively regulates neuronal damage induced by TMT by attenuating oxidative stress.

Altered expression of DJ-1 in the hippocampal cells following in vivo and in vitro neuronal damage induced by trimethyltin.

Trimethyltin chloride (TMT) is known to produce neuronal damage in the dentate gyrus at least in part via oxidative stress. DJ-1, an oncogene product, is known to act as an anti-oxidant to prevent neuronal damage in dopaminergic neurons. The aim of this study was to determine the alterations in DJ-1 expression in the hippocampal cells of mice after in vivo and in vitro treatment with TMT. In naïve animals, DJ-1 was ubiquitously expressed in the hippocampus, in which the CA1 pyramidal cell layer and dentate granule cell layer had lower and higher levels of it, respectively. An intraperitoneal injection of TMT at the dose of 2.8 mg/kg produced DJ-1 up-regulation in the CA1 pyramidal cell layer, CA3 stratum lucidum, dentate molecular layer, and dentate hilus, but not in the dentate granule cell layer, on day 3-5 post-treatment. Temporary depletion of endogenous glutathione by the prior subcutaneous injection of 2-cyclohexen-1-one was effective in facilitating neuronal damage and DJ-1 up-regulation in the dentate gyrus induced by an intraperitoneal injection of TMT at the dose of 2.0 mg/kg. In primary cultures of mouse hippocampal cells, DJ-1 was present in neurons, but not in astrocytes. TMT treatment produced a dramatic expression of DJ-1 in the astrocytes in the cultures. Taken together, our data suggest that the DJ-1 protein is positively regulated in response to oxidative stress induced by TMT.

Acoustic overstimulation facilitates the expression of glutamate-cysteine ligase catalytic subunit probably through enhanced DNA binding of activator protein-1 and/or NF-kappaB in the murine cochlea.

Glutamate-cysteine ligase (GCL), previously known as gamma-glutamylcysteine synthetase, is the rate-limiting enzyme for GSH synthesis. The expression of GCL is mediated by activator protein-1 (AP-1) and nuclear factor-kappa B (NF-kappaB), which are known to participate in stress-induced apoptotic pathways in neuronal cells. In this study, we investigated the changes in the level of these transcription factors as well as of GCL catalytic subunit in the cochlea in response to acoustic overstimulation. Nuclear extracts were prepared from the cochlear at various time points after intense noise exposure (4kHz octave band, 125dB sound pressure level, 5h), and then determined DNA binding activity of the transcription factors. AP-1 DNA binding was markedly increased 2-12h after the noise exposure, with a peak at 2h after the exposure. NF-kappaB DNA binding was also increased immediately after the exposure. Semi-quantitative RT-PCR revealed that the catalytic subunit of GCL mRNA was elevated in the cochlea 2-24h post the exposure. Further immunohistochemical study revealed that increased level of GCL catalytic subunit observed at least in the spiral ganglion cells after the exposure. These results suggest that intense noise exposure facilitates the expression of GCL catalytic subunit in the cochlea possibly through the activation of transcription factors including AP-1 and NF-kappaB.

Activator protein-1 responsive to the group II metabotropic glutamate receptor subtype in association with intracellular calcium in cultured rat cortical neurons.

Activation of ionotropic glutamate (Glu) receptors, such as N-methyl-d-aspartate receptors, is shown to modulate the gene transcription mediated by the transcription factor activator protein-1 (AP1) composed of Fos and Jun family proteins in the brain, while little attention has been paid to the modulation of AP1 expression by metabotropic Glu receptors (mGluRs). In cultured rat cortical neurons, where constitutive expression was seen with all groups I, II and III mGluR subtypes, a significant and selective increase was seen in the DNA binding activity of AP1 120 min after the brief exposure to the group II mGluR agonist (2S,2'R,3'R)-2-(2',3'-dicarboxycyclopropyl)glycine (DCG-IV) for 5 min. In cultured rat cortical astrocytes, by contrast, a significant increase was induced by a group I mGluR agonist, but not by either a group II or III mGluR agonist. The increase by DCG-IV was significantly prevented by a group II mGluR antagonist as well as by either an intracellular Ca(2+) chelator or a voltage-sensitive Ca(2+) channel blocker, but not by an intracellular Ca(2+) store inhibitor. Moreover, DCG-IV significantly prevented the increase of cAMP formation by forskolin in cultured neurons. Western blot analysis revealed differential expression profiles of Fos family members in neurons briefly exposed to DCG-IV and NMDA. Prior or simultaneous exposure to DCG-IV led to significant protection against neuronal cell death by NMDA. These results suggest that activation of the group II mGluR subtype would modulate the gene expression mediated by AP1 through increased intracellular Ca(2+) levels in cultured rat cortical neurons.

Decreased level of mitochondrial RNA by glutamate in cultured cortical neurons.

Mitochondrial injury is induced by a decline in mitochondrial function as well as by damaged mitochondrial DNA. In this study, we evaluate the effects of glutamate exposure on the level of mitochondrial mRNA in cultured cortical neurons of mice. Glutamate exposure for 15 min significantly reduced cell viability 24 h later. Under these experimental conditions, glutamate was effective in reducing the level of mitochondrial mRNAs, especially the mRNAs of NADH-ubiquinone oxidoreductase subunits (nd1 and nd6), 6 h after the exposure. Southern blot analysis, however, revealed no significant change in that of the mitochondrial DNA at any time after glutamate exposure. These results suggest that the activation of glutamate signals negatively regulated the expression of mitochondrial mRNA, without affecting the level of mitochondrial DNA.

Expression of m-Golsyn/Syntabulin gene during mouse brain development.

We recently isolated the cDNA for the mouse Golsyn/Syntabulin (m-Golsyn/Syntabulin) gene and mapped it to mouse chromosome 15B3.2 syntenic with human chromosome 8q23, on which a locus responsible for primary open-angle glaucoma had been located. In the present study, we examined the expression of m-Golsyn/Syntabulin protein in various regions of mouse brain and its developmental changes by use of anti-GOLSYN antibody. m-Golsyn/Syntabulin protein was detected in various brain regions at embryonic day 14 and throughout the postnatal stages. Furthermore, as the histogenesis and maturation of brain proceeded, strong expression of the protein became detectable in cells of the choroid plexus, piriform cortex, pyramidal cell layer, and Purkinje cell layer. In situ hybridization analysis of the mouse brain revealed that localization of the m-Golsyn/Syntabulin transcript was very similar to that of m-Golsyn/Syntabulin protein, confirming the high-level expression of the m-Golsyn/Syntabulin gene in the specific brain regions. High-level expression of m-Golsyn/Syntabulin protein was also observed in the ocular tissues including the ciliary body, which is known as a site for the production of aqueous humor. These results may indicate a significant role for this protein in neuronal cells and other types of cells such as those of the choroid plexus and ciliary body.

Inhibition of RANKL-induced osteoclastogenesis by (-)-DHMEQ, a novel NF-kappaB inhibitor, through downregulation of NFATc1.

UNLABELLED: (-)-DHMEQ, a newly designed NF-kappaB inhibitor, inhibited RANKL-induced osteoclast differentiation in mouse BMMs through downregulation of the induction of NFATc1, an essential transcription factor of osteoclastogenesis. INTRODUCTION: Bone destruction is often observed in advanced case of rheumatoid arthritis and neoplastic diseases, including multiple myeloma. Effective and nontoxic chemotherapeutic agents are expected for the suppression of these bone destructions. RANKL induces activation of NF-kappaB and osteoclastogenesis in bone marrow-derived monocyte/macrophage precursor cells (BMMs). Targeted disruption or pharmacological suppression of NF-kappaB result in impaired osteoclastogenesis, but how NF-kappaB is involved in the regulation of osteoclastogenesis is not known. MATERIALS AND METHODS: The effect of (-)-dehydroxymethylepoxyquinomicin [(-)-DHMEQ] on osteoclast differentiation was studied using a culture system of mouse BMMs stimulated with RANKL and macrophage colony-stimulating factor. The mechanism of the inhibition was studied by biochemical analysis such as immunoblotting and retroviral transfer experiments. RESULTS: (-)-DHMEQ strongly inhibited RANKL-induced NF-kappaB activation in BMMs and inhibited RANKL-induced formation of TRACP(+) multinucleated cells. Interestingly, (-)-DHMEQ specifically inhibited the RANKL-induced expression of NFATc1 but not the expressions of TRAF6 or c-fos. Inhibition of osteoclast differentiation by (-)-DHMEQ was rescued by overexpression of NFATc1, suggesting that the inhibition is not caused by a toxic effect. Moreover, pit formation assays showed that (-)-DHMEQ also inhibited the bone-resorbing activity of mature osteoclasts. CONCLUSION: The inhibition of NF-kappaB suppresses osteoclastogenesis by downregulation of NFATc1, suggesting that NFATc1 expression is regulated by NF-kappaB in RANKL-induced osteoclastogenesis. Our results also indicate the possibility of (-)-DHMEQ becoming a new therapeutic strategy against bone erosion.

In vivo treatment with the K+ channel blocker 4-aminopyridine protects against kainate-induced neuronal cell death through activation of NMDA receptors in murine hippocampus.

Activation of NMDA receptors has been shown to induce either neuronal cell death or neuroprotection against excitotoxicity in cultured neurons in vitro. To elucidate in vivo neuroprotective role of NMDA receptors, we investigated the effects of activation of NMDA receptors by endogenous glutamate on kainate-induced neuronal damage to the mouse hippocampus in vivo. The systemic administration of the K+ channel blocker 4-aminopyridine (4-AP, 5 mg/kg, i.p.) induced expression of c-Fos in the hippocampal neuronal cell layer, which expression was completely abolished by the noncompetitive NMDA receptor antagonist MK-801, thus indicating that the administration of 4-AP would activate NMDA receptors in the hippocampal neurons. The prior administration of 4-AP at 1 h to 1 day before significantly prevented kainate-induced pyramidal cell death in the hippocampus and expression of pyramidal cells immunoreactive with an antibody against single-stranded DNA. Further immunohistochemical study on deoxyribonuclease II revealed that the pretreatment with 4-AP led to complete abolition of deoxyribonuclease II expression induced by kainate in the CA1 and CA3 pyramidal cells. The neuroprotection mediated by 4-AP was blocked by MK-801 and by the adenosine A1 antagonist 8-cyclopenthyltheophylline. Taken together, in vivo activation of NMDA receptors is capable of protecting against kainate-induced neuronal damage through blockade of DNA fragmentation induced by deoxyribonuclease II in the murine hippocampus.

In vivo activation of c-Jun N-terminal kinase signaling cascade prior to granule cell death induced by trimethyltin in the dentate gyrus of mice.

The systemic administration of trimethyltin (TMT, 2.8 mg/kg, i.p.) induced granule cell death in the mouse dentate gyrus selectively 2 days later. The administration of TMT not only enhanced activator protein-1 DNA binding, along with an increase in expression of c-Jun and Fra-2, in the hippocampus 1 day later, but also facilitated phosphorylation of c-Jun N-terminal kinase (JNK) within the cytosol and nucleus. There was also a concomitant increase in the level of phosphorylated JNK kinase (MKK4/SEK1) in the cytosol 16-24 h after the administration. Moreover, TMT markedly elevated endogenous levels of both phosphorylated c-Jun and phosphorylated activating transcription factor-2 (ATF-2), in addition to activating JNK activity in the nuclear extracts obtained 16-24 h post-administration. Immunohistochemical analysis revealed that whereas Fra-2 and phosphorylated ATF-2 were expressed in the CA1 pyramidal cell layer predominantly, phosphorylated c-Jun was observed in both the CA1 pyramidal and dentate granule cell layers after TMT administration. Taken together, our data indicate that TMT activates the JNK pathway in the hippocampus prior to neuronal cell death. The prior activation of this pathway could be at least in part involved in the TMT-induced neural damage seen in the dentate granule cells of mice.

Opposing roles of glucocorticoid receptor and mineralocorticoid receptor in trimethyltin-induced cytotoxicity in the mouse hippocampus.

The organotin trimethyltin (TMT) is known to cause neuronal degeneration in the murine brain. Earlier studies indicate that TMT-induced neuronal degeneration is enhanced by adrenalectomy and prevented by exogenous glucocorticoid. The aim of this study was to investigate the regulation of TMT neuroxicity by corticosterone receptors including type I (mineralocorticoid receptor, MR) and type II (glucocorticoid receptor, GR) in adult mice. The systemic injection of TMT at the dose of 2.0 or 2.8 mg/kg produced a marked elevation in the level of plasma corticosterone that was both dose and time dependent. The MR agonist aldosterone had the ability to exacerbate TMT cytotoxicity in the dentate granule cell layer, whereas its antagonist spironolactone protected neurons from TMT cytotoxicity there. In contrast, the GR antagonist mifepristone exacerbated the TMT cytotoxicity. Taken together, our data suggest TMT cytotoxicity is oppositely regulated by GR and MR signals, being exacerbated by MR activation in adult mice.

Inhibition of inflammatory mediator secretion by (-)-DHMEQ in mouse bone marrow-derived macrophages.

Previously, we designed and synthesized a new NF-kappaB inhibitor, dehydroxymethylepoxyquinomicin (DHMEQ), and found that racemic DHMEQ inhibited cytokine secretion and phagocytosis by cells of the macrophage cell line RAW264.7. In the present research, we looked into the effect of optically active (-)-DHMEQ on the NO production, inflammatory cytokine secretion, and prostaglandin secretion in mouse bone marrow-derived macrophages (BMMs). We also studied the effect of (-)-DHMEQ on the differentiation of macrophages. DHMEQ inhibited lipopolysaccharide (LPS)-induced NF-kappaB activation. It also inhibited the expression of inducible NO synthase (iNOS) and NO production induced by LPS. Using enzyme-linked immunosorbent assays, we showed DHMEQ to inhibit LPS-induced secretion of IL-6 and TNF-alpha. It also inhibited COX-2 expression and prostaglandin E(2) production and secretion. It did not inhibit the phagocytosis of fluorescently labeled Escherichia coli by BMMs treated with LPS, unlike in the case of RAW264.7 cells. Next we examined the effect of the inhibitor on M-CSF-induced differentiation of bone marrow cells to macrophages. DHMEQ showed no effect on the differentiation in terms of reactive oxygen species production and F4/80 expression. However, although BMM incorporated oxidized LDL to give rise to foam cells, the (-)-DHMEQ-treated bone marrow cells did not take up oxidized LDL. Taken together, our data show that (-)-DHMEQ inhibited LPS-induced activation of BMM in terms of NO and cytokine secretion, but its effect on phagocytosis differed between BMMs and RAW264.7 cells. We also found that the functional differentiation into macrophages was inhibited by (-)-DHMEQ.

High susceptibility of cortical neural progenitor cells to trimethyltin toxicity: involvement of both caspases and calpain in cell death.

Neural progenitor cells play an essential role in both the developing embryonic nervous system and in the adult brain, where the capacity for self-renewal would be important for normal brain functions. In the present study, we used embryonic cortical neural progenitor cells to investigate the effects of trimethyltin chloride (TMT) on the survival of neural progenitor cells. In cultures of cortical neural progenitor cells, the formation of round neurospheres was observed in the presence of epidermal growth factor and basic fibroblast growth factor within 9 days in vitro. The neurospheres were then harvested for subsequent replating and culturing for assessment of cell viability in either the presence or absence of TMT at the concentration of 5microM. Lasting exposure to TMT produced not only nuclear condensation in the cells in a time-dependent manner over a period of 6-24h, but also the release of lactate dehydrogenase into the culture medium. Immunoblot and immunocytochemical analyses revealed that TMT had the ability to activate both caspase-3 and calpain, as well as to cause nuclear translocation of deoxyribonuclease II, which is located within cytoplasm in intact cells. Additionally, treatment with a calpain inhibitor [trans-epoxysuccinyl-l-leucylamido-(4-guanidino) butane] and a caspase inhibitor [Z-Val-Ala-Asp(OMe)-CH2F] produced a significant reduction in damaged cells induced by TMT. Taken together, our data indicate that neural progenitor cells are highly susceptible to TMT in undergoing cell death via the activation of 2 parallel pathways, ones involving calpain and the other, caspase-3.

Activation of c-Jun N-terminal kinase cascades is involved in part of the neuronal degeneration induced by trimethyltin in cortical neurons of mice.

The organotin trimethyltin (TMT) is known to cause neuronal degeneration in the central nervous system. A systemic injection of TMT produced neuronal damage in the cerebral frontal cortex of mice. To elucidate the mechanism(s) underlying the toxicity of TMT toward neurons, we prepared primary cultures of neurons from the cerebral cortex of mouse embryos for use in this study. Microscopic observations revealed that a continuous exposure to TMT produced neuronal damage with nuclear condensation in an incubation time-dependent manner up to 48 h. The neuronal damage induced by TMT was not blocked by N-methyl-D-aspartate receptor channel-blocker MK-801. The exposure to TMT produced an elevation of the phosphorylation level of c-Jun N-terminal kinase (JNK)(p46), but not JNK(p54), prior to neuronal death. Under the same conditions, a significant elevation was seen in the phosphorylation level of stress-activated protein kinase 1, which activates JNKs. Furthermore, TMT enhanced the expression and phosphorylation of c-Jun during a continuous exposure. The JNK inhibitor SP600125 was effective in significantly but only partially attenuating the TMT-induced nuclear condensation and accumulation of lactate dehydrogenase in the culture medium. Taken together, our data suggest that the neuronal damage induced by TMT was independent of excitotoxicity but that at least some of it was dependent on the JNK cascades in primary cultures of cortical neurons.

Endogenous and exogenous glucocorticoids prevent trimethyltin from causing neuronal degeneration of the mouse brain in vivo: involvement of oxidative stress pathways.

The organotin trimethyltin (TMT) is known to cause neuronal degeneration in the murine brain. Earlier studies indicate that TMT-induced neuronal degeneration is enhanced by adrenalectomy. However, no evaluation has been attempted to determine the mechanism underlying the enhancement of TMT neurotoxicity by adrenalectomy and its implications in neuronal degeneration. To assess the implications and determine the mechanism of adrenalectomy-elicited enhancement of TMT neurotoxicity, we examined neuronal degeneration and associated signaling pathways in adrenalectomized mice. Adrenalectomy dramatically enhanced the TMT-induced neuronal damage in certain brain regions including the dentate gyrus, olfactory bulb, and anterior olfactory nucleus, in addition to exacerbating the behavioral abnormalities. TMT-induced activation of caspase-3 and calpain was also enhanced by adrenalectomy. The above events elicited by TMT were almost entirely prevented by treatment with dexamethasone. In addition to the above events, adrenalectomy clearly enhanced the activation of c-Jun-N-terminal kinases and the formation of 4-hydroxynonenal in the dentate gyrus following TMT treatment. The dentate granule cell damage induced by TMT was exacerbated by mifepristone, a glucocorticoid-receptor antagonist. Taken together, our data suggest that endogenous and exogenous glucocorticoids prevent neurodegeneration induced by TMT in the central nervous system by attenuating intensive oxidative stress and associated signaling pathways.

Transcriptional factors in the cochlea within the inner ear.

Differential regulation of gene expression by transcription factors is widely viewed as one of the principal mechanisms guiding development. Although numerous DNA binding proteins have been identified in various tissues, the role of individual transcription factors in the differentiation of specific cell groups, such as those populating the inner ear, is just beginning to be elucidated. It is known that transcription factors are induced in response to many signals that lead to cell growth, differentiation, inflammatory responses, the regulation of apoptosis, and neoplastic transformation. There are various transcription factors in the cochlea of the inner ear. These include activator protein-1 and nuclear factor-kappa B, glucocorticoid receptor, and so on. Based on recent reports and our investigation, in this article we review possible functions and expression of these transcription factors.