Formation of methylselenol, dimethylselenide and dimethyldiselenide in in vitro metabolism models determined by headspace GC-MS

Charlotte Gabel-Jensen; Kristoffer Lunøe; Bente Gammelgaard

doi:10.1039/b914255j

Formation of methylselenol, dimethylselenide and dimethyldiselenide in in vitro metabolism models determined by headspace GC-MS

Charlotte Gabel-Jensen, Kristoffer Lunøe, Bente Gammelgaard

28 Citations (Scopus)

Abstract

The aim of this study was to identify the presence of MeSeH in metabolic reactions. An analytical method based on direct headspace GC-MS, eliminating loss of volatile species during sample pretreatment procedures, was developed for this purpose. The in vitro conversion of selenium compounds to the volatile species methylselenol, MeSeH, dimethyl selenide, DMeSe and dimethyl diselenide, DMeDSe was investigated. The analytical method was evaluated by means of standards of dimethyl diselenide, dimethyl selenide. The corresponding sulfides were found unsuitable as internal standards as they interacted with the selenides. The limit of detection was 0.25 μmol L^-1 (20 μg L^-1) for the selenide as well as the diselenide. Formation of MeSeH was not observed in significant amount when selenomethionine was incubated with the enzyme l-methionine-γ-lyase; instead large amounts of DMeDSe were formed. In aqueous solution, methylseleninic acid, MeSeA reacted spontaneously with glutathione, GSH to form DMeDSe. In strongly reducing environments, however, MeSeH was also observed. When the formed MeSeH was trapped with iodoacetic acid, no DMeDSe was detected indicating that DMeDSe formation was due to spontaneous oxidation of MeSeH. These findings imply that DMeDSe may be a marker for the production of MeSeH in in vitro models. When MeSeA, Se-methylselenocysteine, Se-MeSeCys and SeMet were incubated with Jurkat cells, DMeDSe formation was only observed in the case of MeSeA. Trace amounts of DMeSe was observed in the vial with MeSeA as well as Se-MeSeCys. When DMeSe and DMeDSe were added to plasma, the sensitivity of only DMeDSe decreased significantly, implicating that DMeDSe underwent a reaction with plasma hindering the volatilization. This emphasizes that results from in vitro selenium metabolism studies may not be uncritically interpreted as consistent with the in vivo reality.

Original language	English
Journal	Metallomics
Volume	2
Pages (from-to)	167-173
ISSN	1756-5901
DOIs	https://doi.org/10.1039/b914255j
Publication status	Published - 2010

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Former Faculty of Pharmaceutical Sciences

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https://academic.oup.com/metallomics/article-pdf/2/2/167/34836405/b914255j.pdf

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@article{3a277f1085c611df928f000ea68e967b,

title = "Formation of methylselenol, dimethylselenide and dimethyldiselenide in in vitro metabolism models determined by headspace GC-MS",

abstract = "The aim of this study was to identify the presence of MeSeH in metabolic reactions. An analytical method based on direct headspace GC-MS, eliminating loss of volatile species during sample pretreatment procedures, was developed for this purpose. The in vitro conversion of selenium compounds to the volatile species methylselenol, MeSeH, dimethyl selenide, DMeSe and dimethyl diselenide, DMeDSe was investigated. The analytical method was evaluated by means of standards of dimethyl diselenide, dimethyl selenide. The corresponding sulfides were found unsuitable as internal standards as they interacted with the selenides. The limit of detection was 0.25 μmol L-1 (20 μg L-1) for the selenide as well as the diselenide. Formation of MeSeH was not observed in significant amount when selenomethionine was incubated with the enzyme l-methionine-γ-lyase; instead large amounts of DMeDSe were formed. In aqueous solution, methylseleninic acid, MeSeA reacted spontaneously with glutathione, GSH to form DMeDSe. In strongly reducing environments, however, MeSeH was also observed. When the formed MeSeH was trapped with iodoacetic acid, no DMeDSe was detected indicating that DMeDSe formation was due to spontaneous oxidation of MeSeH. These findings imply that DMeDSe may be a marker for the production of MeSeH in in vitro models. When MeSeA, Se-methylselenocysteine, Se-MeSeCys and SeMet were incubated with Jurkat cells, DMeDSe formation was only observed in the case of MeSeA. Trace amounts of DMeSe was observed in the vial with MeSeA as well as Se-MeSeCys. When DMeSe and DMeDSe were added to plasma, the sensitivity of only DMeDSe decreased significantly, implicating that DMeDSe underwent a reaction with plasma hindering the volatilization. This emphasizes that results from in vitro selenium metabolism studies may not be uncritically interpreted as consistent with the in vivo reality.",

keywords = "Former Faculty of Pharmaceutical Sciences",

author = "Charlotte Gabel-Jensen and Kristoffer Lun{\o}e and Bente Gammelgaard",

year = "2010",

doi = "10.1039/b914255j",

language = "English",

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pages = "167--173",

journal = "Metallomics",

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T1 - Formation of methylselenol, dimethylselenide and dimethyldiselenide in in vitro metabolism models determined by headspace GC-MS

AU - Gabel-Jensen, Charlotte

AU - Lunøe, Kristoffer

AU - Gammelgaard, Bente

PY - 2010

Y1 - 2010

N2 - The aim of this study was to identify the presence of MeSeH in metabolic reactions. An analytical method based on direct headspace GC-MS, eliminating loss of volatile species during sample pretreatment procedures, was developed for this purpose. The in vitro conversion of selenium compounds to the volatile species methylselenol, MeSeH, dimethyl selenide, DMeSe and dimethyl diselenide, DMeDSe was investigated. The analytical method was evaluated by means of standards of dimethyl diselenide, dimethyl selenide. The corresponding sulfides were found unsuitable as internal standards as they interacted with the selenides. The limit of detection was 0.25 μmol L-1 (20 μg L-1) for the selenide as well as the diselenide. Formation of MeSeH was not observed in significant amount when selenomethionine was incubated with the enzyme l-methionine-γ-lyase; instead large amounts of DMeDSe were formed. In aqueous solution, methylseleninic acid, MeSeA reacted spontaneously with glutathione, GSH to form DMeDSe. In strongly reducing environments, however, MeSeH was also observed. When the formed MeSeH was trapped with iodoacetic acid, no DMeDSe was detected indicating that DMeDSe formation was due to spontaneous oxidation of MeSeH. These findings imply that DMeDSe may be a marker for the production of MeSeH in in vitro models. When MeSeA, Se-methylselenocysteine, Se-MeSeCys and SeMet were incubated with Jurkat cells, DMeDSe formation was only observed in the case of MeSeA. Trace amounts of DMeSe was observed in the vial with MeSeA as well as Se-MeSeCys. When DMeSe and DMeDSe were added to plasma, the sensitivity of only DMeDSe decreased significantly, implicating that DMeDSe underwent a reaction with plasma hindering the volatilization. This emphasizes that results from in vitro selenium metabolism studies may not be uncritically interpreted as consistent with the in vivo reality.

AB - The aim of this study was to identify the presence of MeSeH in metabolic reactions. An analytical method based on direct headspace GC-MS, eliminating loss of volatile species during sample pretreatment procedures, was developed for this purpose. The in vitro conversion of selenium compounds to the volatile species methylselenol, MeSeH, dimethyl selenide, DMeSe and dimethyl diselenide, DMeDSe was investigated. The analytical method was evaluated by means of standards of dimethyl diselenide, dimethyl selenide. The corresponding sulfides were found unsuitable as internal standards as they interacted with the selenides. The limit of detection was 0.25 μmol L-1 (20 μg L-1) for the selenide as well as the diselenide. Formation of MeSeH was not observed in significant amount when selenomethionine was incubated with the enzyme l-methionine-γ-lyase; instead large amounts of DMeDSe were formed. In aqueous solution, methylseleninic acid, MeSeA reacted spontaneously with glutathione, GSH to form DMeDSe. In strongly reducing environments, however, MeSeH was also observed. When the formed MeSeH was trapped with iodoacetic acid, no DMeDSe was detected indicating that DMeDSe formation was due to spontaneous oxidation of MeSeH. These findings imply that DMeDSe may be a marker for the production of MeSeH in in vitro models. When MeSeA, Se-methylselenocysteine, Se-MeSeCys and SeMet were incubated with Jurkat cells, DMeDSe formation was only observed in the case of MeSeA. Trace amounts of DMeSe was observed in the vial with MeSeA as well as Se-MeSeCys. When DMeSe and DMeDSe were added to plasma, the sensitivity of only DMeDSe decreased significantly, implicating that DMeDSe underwent a reaction with plasma hindering the volatilization. This emphasizes that results from in vitro selenium metabolism studies may not be uncritically interpreted as consistent with the in vivo reality.

KW - Former Faculty of Pharmaceutical Sciences

U2 - 10.1039/b914255j

DO - 10.1039/b914255j

M3 - Journal article

C2 - 21069149

SN - 1756-5901

VL - 2

SP - 167

EP - 173

JO - Metallomics

JF - Metallomics

ER -

Formation of methylselenol, dimethylselenide and dimethyldiselenide in in vitro metabolism models determined by headspace GC-MS

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