Dimethylthioarsenicals as Arsenic Metabolites and Their Chemical Preparations

Suzuki, Kazuo; Mandal, Badal Kumar; Katagiri, Akio; Sakuma, Yoshiharu; Kawakami, Ayumi; Ogra, Yasumitsu; Yamaguchi, Kentaro; Sei, Yoshihisa; Yamanaka, Kazuhiro; Anzai, Kazunori; Ohmichi, Masayoshi; Takayama, Hiromitsu; Aimi, Noriro

doi:10.1021/tx049963s

Cited by 108 publications

(95 citation statements)

References 31 publications

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“…Regarding the detection of DMA(III) in urine, it has recently been reported that DMA(III) has been mistaken for a sulfur-containing dimethylarsenic compound (Hansen et al, 2004;Suzuki et al, 2004aSuzuki et al, , 2004b. These results were based on mass spectral analysis of several products formed from DMA(V) by reacting it directly with sulfur-containing compounds under acidic conditions.…”

Section: Discussionmentioning

confidence: 99%

“…In contrast, monomethylarsonous acid (MMA(III)) (trivalent monomethylarsenic) was readily methylated in vitro to dimethylarsenic (Styblo et al, , 1999. Recent studies with trivalent monomethylarsenic, formed by reacting MMA(V) with thiols, and administered po (0.1-0.5 mg/ kg) or iv (0.5 mg/kg) (Suzuki et al, 2004b) to rats showed that it was methylated to DMA(V). The low rate of conversion of MMA(V) is surprising, given the relative rapidity of iAs methylation by many species.…”

Section: Introductionmentioning

confidence: 99%

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Tissue dosimetry, metabolism and excretion of pentavalent and trivalent monomethylated arsenic in mice after oral administration

Hughes

Devesa

Adair

et al. 2005

Toxicology and Applied Pharmacology

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Exposure to monomethylarsonic acid (MMA(V)) and monomethylarsonous acid (MMA(III)) can result from their formation as metabolites of inorganic arsenic and by the use of the sodium salts of MMA(V) as herbicides. This study compared the disposition of MMA(V) and MMA(III) in adult female B6C3F1 mice. Mice were gavaged po with MMA(V), either unlabeled or labeled with 14 C at two dose levels (0.4 or 40 mg As/kg). Other mice were dosed po with unlabeled MMA(III) at one dose level (0.4 mg As/kg). Mice were housed in metabolism cages for collection of excreta and sacrificed serially over 24 h for collection of tissues. MMA(V)-derived radioactivity was rapidly absorbed, distributed and excreted. By 8 h post-exposure, 80% of both doses of MMA(V) were eliminated in urine and feces. Absorption of MMA(V) was dose dependent; that is, there was less than a 100-fold difference between the two dose levels in the area under the curves for the concentration-time profiles of arsenic in blood and major organs. In addition, urinary excretion of MMA(V)-derived radioactivity in the low dose group was significantly greater (P < 0.05) than in the high dose group. Conversely, fecal excretion of MMA(V)-derived radioactivity was significantly greater (P < 0.05) in the high dose group than in the low dose group. Speciation of arsenic by hydride generation-atomic absorption spectrometry in urine and tissues of mice administered MMA(V) or MMA(III) found that methylation of MMA(V) was limited while the methylation of MMA(III) was extensive. Less than 10% of the dose excreted in urine of MMA(V)-treated mice was in the form of methylated products, whereas it was greater than 90% for MMA(III)-treated mice. In MMA(V)-treated mice, 25% or less of the tissue arsenic was in the form of dimethylarsenic, whereas in MMA (III)-treated mice, 75% or more of the tissue arsenic was in the form of dimethylarsenic. Based on urinary analysis, administered dose of MMA(V) did not affect the level of its metabolites excreted. In the tested range, dose affects the absorption, distribution and route of excretion of MMA(V) but not its metabolism.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tissue dosimetry, metabolism and excretion of pentavalent and trivalent monomethylated arsenic in mice after oral administration

Hughes

Devesa

Adair

et al. 2005

Toxicology and Applied Pharmacology

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“…For instance, arsinothioyls confound identification by HPLC, pH-selective HG-ICP-MS, or anionexchange chromatography. [35,36] Formation in vitro or in vivo of thioylated metabolites by rat liver [37,38] may require enzymatic generation of hydrogen sulfide. [39] Understanding formation of arsinothioyls and their biological activities will provide more information about roles of metabolism in the actions of arsenicals as toxins and carcinogens.…”

Section: Problems and Prospects For Future Researchmentioning

confidence: 99%

Commonalities in Metabolism of Arsenicals

Adair¹,

Waters²,

Devesa³

et al. 2005

Environ. Chem.

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Abstract. Elucidating the pathway of inorganic arsenic metabolism shows that some of methylated arsenicals formed as intermediates and products are reactive and toxic species. Hence, methylated arsenicals likely mediate at least some of the toxic and carcinogenic effects associated with exposure to arsenic. Trimethylarsonium compounds and arsenosugars are two other classes of arsenicals to which humans are routinely exposed and there is evidence that both classes are metabolized to produce methylated arsenicals. Here, we review evidence for production of methylated metabolism and consider the challenges posed in unraveling a complex web for metabolism of arsenicals in humans.

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“…. The predominant forms of arsenic in drinking water are arsenite and arsenate (iAs III and iAs", respectively), the inorganic species which are regarded as human carcinogens [2,3]. Inorganic arsenic compounds are transformed in the body by repetitive reduction and oxidative methylation reactions, leading to the formation of organoarsenic species, the major of which are monomethylarsonic acid (MMAv) and dimethylarsinic acid (DMAV) [3,4].…”

mentioning

confidence: 99%

“…The predominant forms of arsenic in drinking water are arsenite and arsenate (iAs III and iAs", respectively), the inorganic species which are regarded as human carcinogens [2,3]. Inorganic arsenic compounds are transformed in the body by repetitive reduction and oxidative methylation reactions, leading to the formation of organoarsenic species, the major of which are monomethylarsonic acid (MMAv) and dimethylarsinic acid (DMAV) [3,4].The precise pathway through which inorganic arsenic is metabolized in the organism is not yet known in sufficient detail. The generally accepted methylation mechanism involves the initial conversion of pentavalent arsenic species iAsv to trivalent species iAs IlI through a two-electron reduction, while oxidative addition of a methyl group follows [4,5].…”

mentioning

confidence: 99%

Development of mass spectrometric methods for detecting arsenic-glutathione complexes

Kanaki

Pergantis

2008

J. Am. Soc. Mass Spectrom.

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It has been suggested recently that arsenic-glutathione (As-GSH) complexes play an important role in the methylation of arsenic. The present study describes the development of high-performance liquid chromatography (HPLC)-electrospray tandem mass spectrometry (ES-MS/MS), operated in the selected reaction monitoring (SRM) mode, and HPLCinductively coupled plasma mass spectrometry (ICP-MS) methods suitable for the sensitive and selective identification of four As-GSH complexes. Method optimization was carried out using a series of synthetically prepared standards, i.e., three As-GSH species containing trivalent arsenic: tri(glutamyl-cysteinyl-glycinyl)trithio-arsenite (ATG), di(glutamyl-cysteinyl-glycinyl)methy1-dithio-arsonite (MAOC), and (a-glutemyl-cysteinyl-glycinyl) dimethyl-thio-arsinite (DMAG), as well as one As-GSH species containing pentavalent As: dimethylthioarsinic acid-glutathione (DMTAv-GSH). The collision induced dissociation behavior of these compounds was investigated in detail to identify optimum SRM transitions for each complex. Both methods were based on reversed-phase chromatography using gradient elution with methanol, formic acid, and water as solvents. The amount of methanol that was used with this HPLC method (up to 12% vol/vol) was compatible with ICP-MS, without the need of a specially adapted interface. Subsequently, these analytical methods were applied to carry out a preliminary investigation about the role of As-GSH complexes in the methylation of arsenite by methy1cobalamin (CH 3Bu) in the presence of glutathione (GSH). For the first time, the complexes ATG, MADG, and trace amounts of DMAG were detected as products of this reaction. . The predominant forms of arsenic in drinking water are arsenite and arsenate (iAs III and iAs", respectively), the inorganic species which are regarded as human carcinogens [2,3]. Inorganic arsenic compounds are transformed in the body by repetitive reduction and oxidative methylation reactions, leading to the formation of organoarsenic species, the major of which are monomethylarsonic acid (MMAv) and dimethylarsinic acid (DMAV) [3,4].The precise pathway through which inorganic arsenic is metabolized in the organism is not yet known in sufficient detail. The generally accepted methylation mechanism involves the initial conversion of pentavalent arsenic species iAsv to trivalent species iAs IlI through a two-electron reduction, while oxidative addition of a methyl group follows [4,5]. Glutathione (GSH) can act as a reducing agent and 5-adenosylmethionine (SAM) as a methyl donor. The major site for the methylation seems to be the liver. However, Hayakawa et al. recently proposed Address reprint requests to Dr. S. A. Pergantis, Environmental Chemical Processes Laboratory, Department of Chemistry, University of Crete, Voutes, Heraklion 71003, Crete, Greece. E-mail: spergantis@chemistry. uoc.gr an altemative mechanism for the methylation of inorganic arsenic in biological systems [6]. According to this methylation mechanism, complexes of arsenic with gluta...

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Dimethylthioarsenicals as Arsenic Metabolites and Their Chemical Preparations

Cited by 108 publications

References 31 publications

Tissue dosimetry, metabolism and excretion of pentavalent and trivalent monomethylated arsenic in mice after oral administration

Tissue dosimetry, metabolism and excretion of pentavalent and trivalent monomethylated arsenic in mice after oral administration

Commonalities in Metabolism of Arsenicals

Development of mass spectrometric methods for detecting arsenic-glutathione complexes

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