Alterations in xenobiotic metabolism in the long-lived Little mice

Our previous microarray expression analysis of the long-lived Little mice (Ghrhr(lit/lit)) showed a concerted up-regulation of xenobiotic detoxification genes. Here, we show that this up-regulation is associated with a potent increase in resistance against the adverse effects of a variety of xenobiotics, including the hepatotoxins acetaminophen and bromobenzene and the paralyzing agent zoxazolamine. The classic xenobiotic receptors Car (Constitutive Androstane Receptor) and Pxr (Pregnane X Receptor) are considered key regulators of xenobiotic metabolism. Using double and triple knockout/mutant mouse models we found, however, that Car and Pxr are not required for the up-regulation of xenobiotic genes in Little mice. Our results suggest instead that bile acids and the primary bile acid receptor Fxr (farnesoid X receptor) are likely mediators of the up-regulation of xenobiotic detoxification genes in Little mice. Bile acid levels are considerably elevated in the bile, serum, and liver of Little mice. We found that treatment of wild-type animals with cholic acid, one of the major bile acids elevated in Little mice, mimics in large part the up-regulation of xenobiotic detoxification genes observed in Little mice. Additionally, the loss of Fxr had a major effect on the expression of the xenobiotic detoxification genes up-regulated in Little mice. A large fraction of these genes lost or decreased their high expression levels in double mutant mice for Fxr and Ghrhr. The alterations in xenobiotic metabolism in Little mice constitute a form of increased stress resistance and may contribute to the extended longevity of these mice.     

Peroxisome proliferator-activated receptor alpha plays a vital role in inducing a detoxification system against plant compounds with crosstalk with other xenobiotic nuclear receptors

Peroxisome proliferator-activated receptor alpha (PPARalpha) is thought to play an important role in lipid metabolism in the liver. To clarify the extra-hepatic and/or unknown function of PPARalpha, we previously performed a proteome analysis of the intestinal proteins and identified 17beta-hydroxysteroid dehydrogenase type 11 as a mostly induced protein by a PPARalpha ligand [Motojima, K. (2004) Eur. J. Biochem. 271, 4141-4146]. Because of its supposed wide substrate specificity, we examined the possibility that PPARalpha plays an important role in inducing detoxification systems for some natural foods by feeding mice with various plant seeds and grains. Feeding with sesame but not others often killed PPARalpha knockout mice but not wild-type mice. A microarray analysis of the sesame-induced mRNAs in the intestine revealed that PPARalpha plays a vital role in inducing various xenobiotic metabolizing enzymes in the mouse intestine and liver. A PPARalpha ligand alone could not induce most of these enzymes, suggesting that there is an essential crosstalk among PPARalpha and other xenobiotic nuclear receptors to induce a detoxification system for plant compounds.     

Melatonin and its metabolites: new findings regarding their production and their radical scavenging actions

This review summarizes some of the recent findings concerning the long-held tenet that the enzyme, N-acetyltransferase, which is involved in the production of N-acetylserotonin, the immediate precursor of melatonin, may in fact not always control the quantity of melatonin generated. New evidence from several different laboratories indicates that hydroxyindole-O-methyltransferase, which O-methylates N-acetylserotonin to melatonin may be rate-limiting in some cases. Also, the review makes the point that melatonin's actions are uncommonly widespread in organs due to the fact that it works via membrane receptors, nuclear receptors/binding sites and receptor-independent mechanisms, i.e., the direct scavenging of free radicals. Finally, the review briefly summarizes the actions of melatonin and its metabolites in the detoxification of oxygen and nitrogen-based free radicals and related non-radical products. Via these multiple processes, melatonin is capable of influencing the metabolism of every cell in the organism.     

重金属与农药污染的农业土壤脱毒过程研究进展

农业土壤环境自身脱毒过程是极其复杂的生态化学过程,对于土壤健康质量的维持和改善具有重要意义。然而,一直以来,人们对污染物的致毒过程研究得较多,对农业土壤自身脱毒能力及机制未给予足够重视。本文就农业土壤环境中,重金属与农药污染物的吸附脱毒、非生物降解(水解、光解)脱毒、微生物降解脱毒、土壤酶学脱毒、根际环境中的降解和转化脱毒以及植物富集固定进行了综述,并分析了各脱毒过程中所涉及到的反应机理。     

Regulation of the aldo-keto reductase gene akr1b7 by the nuclear oxysterol receptor LXRalpha (liver X receptor-alpha) in the mouse intestine: putative role of LXRs in lipid detoxification processes

Liver X receptors (LXRs) regulate the expression of a number of genes involved in cholesterol and lipid metabolism after activation by their cognate oxysterol ligands. AKR1-B7 (aldo-keto reductase 1-B7) is expressed in LXR target tissues such as intestine, and because of its known role in detoxifying lipid peroxides, we investigated whether the AKR1-B7 detoxification pathway was regulated by LXRs. Here we show that synthetic LXR agonists increase the accumulation of AKR1-B7 mRNA and protein levels in mouse intestine in wild-type but not lxr(-/-) mice. Regulation of akr1b7 by retinoic X receptor/LXR heterodimers is dependent on three response elements in the proximal murine akr1b7 promoter. Two of these cis-acting elements are specific for regulation by the LXRalpha isoform. In addition, in duodenum of wild-type mice fed a synthetic LXR agonist, we observed an LXR-dependent decrease in lipid peroxidation. Our results demonstrate that akr1b7 is a direct target of LXRs throughout the small intestine, and that LXR activation plays a protective role by decreasing the deleterious effects of lipid peroxides in duodenum. Taken together, these data suggest a new role for LXRs in lipid detoxification.     

过氧化氢脱毒前后小桐子油饼营养成分分析

小桐子(Jatropha curcas Linn.)又名麻疯树,属于大戟科(Euphorbiaceae)麻疯树属(Jatropha Linn.)植物,在中国西南各省均有大规模种植基地。小桐子树皮和叶片具有多种生物活性[1-2];种子含丰富油脂,可作为生物柴油的原料[3]。小桐子油饼是一种在小桐子生物柴油生产过程中大量产生的副产品,其中的蛋白质含量较高、氨基酸组成合理,是优     

Glutamine synthetase activity and glutamine content in brain: modulation by NMDA receptors and nitric oxide

Acute intoxication with large doses of ammonia leads to rapid death. The main mechanism for ammonia elimination in brain is its reaction with glutamate to form glutamine. This reaction is catalyzed by glutamine synthetase and consumes ATP. In the course of studies on the molecular mechanism of acute ammonia toxicity, we have found that glutamine synthetase activity and glutamine content in brain are modulated by NMDA receptors and nitric oxide. The main findings can be summarized as follows.Blocking NMDA receptors prevents ammonia-induced depletion of brain ATP and death of rats but not the increase in brain glutamine, indicating that ammonia toxicity is not due to increased activity of glutamine synthetase or formation of glutamine but to excessive activation of NMDA receptors.Blocking NMDA receptors in vivo increases glutamine synthetase activity and glutamine content in brain, indicating that tonic activation of NMDA receptors maintains a tonic inhibition of glutamine synthetase.Blocking NMDA receptors in vivo increases the activity of glutamine synthetase assayed in vitro, indicating that increased activity is due to a covalent modification of the enzyme. Nitric oxide inhibits glutamine synthetase, indicating that the covalent modification that inhibits glutamine synthetase is a nitrosylation or a nitration.Inhibition of nitric oxide synthase increases the activity of glutamine synthetase, indicating that the covalent modification is reversible and it must be an enzyme that denitrosylate or denitrate glutamine synthetase.NMDA mediated activation of nitric oxide synthase is responsible only for part of the tonic inhibition of glutamine synthetase. Other sources of nitric oxide are also contributing to this tonic inhibition.Glutamine synthetase is not working at maximum rate in brain and its activity may be increased pharmacologically by manipulating NMDA receptors or nitric oxide content. This may be useful, for example, to increase ammonia detoxification in brain in hyperammonemic situations.     

Role of physiological factors in predicting the risk of oncological diseases on the basis of the polymorphism of the xenobiotic metabolism enzyme system

Summarized recent data on the polymorphism of the xenobiotic metabolism and detoxification enzyme (XMDE) system in humans are presented. The current notions on the molecular mechanisms of metabolic processes and the role of genetic polymorphism are reviewed. The roles of transport proteins and nuclear receptors in the regulation of the activity of the XMDE system are shown. The possibilities of using the polymorphism of the XMDE system as the basis for predicting the risk of oncological diseases are considered. Experimental modeling of different levels of the epoxide synthetase and epoxide hydratase activities revealed their close relationship with the toxic, mutagenic, and carcinogenic actions of polycyclic aromatic hydrocarbons. The data indicating the necessity of considering the physiological factors that could influence xenobiotic metabolism and the development of pathological changes are given.     

Xanthurenic Acid Binds to Neuronal G-Protein-Coupled Receptors That Secondarily Activate Cationic Channels in the Cell Line NCB-20

Xanthurenic acid (XA) is a metabolite of the tryptophan oxidation pathway through kynurenine and 3-hydroxykynurenine. XA was until now considered as a detoxification compound and dead-end product reducing accumulation of reactive radical species. Apart from a specific role for XA in the signaling cascade resulting in gamete maturation in mosquitoes, nothing was known about its functions in other species including mammals. Based upon XA distribution, transport, accumulation and release in the rat brain, we have recently suggested that XA may potentially be involved in neurotransmission/neuromodulation, assuming that neurons presumably express specific XA receptors. Recently, it has been shown that XA could act as a positive allosteric ligand for class II metabotropic glutamate receptors. This finding reinforces the proposed signaling role of XA in brain. Our present results provide several lines of evidence in favor of the existence of specific receptors for XA in the brain. First, binding experiments combined with autoradiography and time-course analysis led to the characterization of XA binding sites in the rat brain. Second, specific kinetic and pharmacological properties exhibited by these binding sites are in favor of G-protein-coupled receptors (GPCR). Finally, in patch-clamp and calcium imaging experiments using NCB-20 cells that do not express glutamate-induced calcium signals, XA elicited specific responses involving activation of cationic channels and increases in intracellular Ca²⁺ concentration. Altogether, these results suggest that XA, acting through a GPCR-induced cationic channel modulatory mechanism, may exert excitatory functions in various brain neuronal pathways.     

Recruitment of young women to a trial of chlamydia screening – as easy as it sounds?

Background

In the United Kingdom (UK), there is an extensive market for the class 'A' drug heroin. Many heroin users spend time in prison. People addicted to heroin often require prescribed medication when attempting to cease their drug use. The most commonly used detoxification agents in UK prisons are buprenorphine, dihydrocodeine and methadone. However, national guidelines do not state a detoxification drug of choice. Indeed, there is a paucity of research evaluating the most effective treatment for opiate detoxification in prisons. This study seeks to address the paucity by evaluating routinely used interventions amongst drug using prisoners within UK prisons.

Methods/Design

The Leeds Evaluation of Efficacy of Detoxification Study (LEEDS) Prisons Pilot Study will use randomised controlled trial methodology to compare the open use of buprenorphine and dihydrocodeine for opiate detoxification, given in the context of routine care, within HMP Leeds. Prisoners who are eligible and give informed consent will be entered into the trial. The primary outcome measure will be abstinence status at five days post detoxification, as determined by a urine test. Secondary outcomes during the detoxification and then at one, three and six months post detoxification will be recorded.