Development of fluorescent-labeled trapping reagents based on cysteine to detect soft and hard electrophilic reactive metabolites

Chikako Shibazaki; Tomoyuki Ohe; Kyoko Takahashi; Shigeo Nakamura; Tadahiko Mashino

doi:10.1016/j.dmpk.2021.100386

Development of fluorescent-labeled trapping reagents based on cysteine to detect soft and hard electrophilic reactive metabolites

Chikako Shibazaki, Tomoyuki Ohe, Kyoko Takahashi, Shigeo Nakamura, Tadahiko Mashino

薬学科

研究成果: Article › 査読

4 被引用数 (Scopus)

抄録

Trapping assays are conducted at lead optimization stages to detect reactive metabolites (RMs) that can contribute to drug toxicity. The commonly used dansyl glutathione (dGSH) provides a sensitive analysis owing to the fluorescent label, however, it captures only soft electrophilic RMs. TRs for hard electrophilic RMs, few of which are labeled fluorescently, can detect hard electrophilic aldehydes only by forming unstable imine derivatives. In this study, we aimed to develop novel fluorescently labeled TRs that detect both soft and hard electrophilic RMs and form stable ring structures with aldehydes. We designed four dansylated TRs based on cysteine, which has both soft and hard nucleophilic groups. To evaluate the reactivity of the TRs, we incubated them with several substrates and found that one of the TRs (CysGlu-Dan) detected all the soft and hard electrophilic RMs. We also examined the inhibition potential of each TR for seven major CYPs involved in drug metabolism and found that CysGlu-Dan showed an inhibitory profile similar to that of dGSH. In conclusion, CysGlu-Dan can be used to evaluate the risk of RMs in drug discovery.

本文言語	English
論文番号	100386
ジャーナル	Drug Metabolism And Pharmacokinetics
巻	39
DOI	https://doi.org/10.1016/j.dmpk.2021.100386
出版ステータス	Published - 2021 8月

ASJC Scopus subject areas

薬理学
薬科学
薬理学（医学）

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10.1016/j.dmpk.2021.100386

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title = "Development of fluorescent-labeled trapping reagents based on cysteine to detect soft and hard electrophilic reactive metabolites",

abstract = "Trapping assays are conducted at lead optimization stages to detect reactive metabolites (RMs) that can contribute to drug toxicity. The commonly used dansyl glutathione (dGSH) provides a sensitive analysis owing to the fluorescent label, however, it captures only soft electrophilic RMs. TRs for hard electrophilic RMs, few of which are labeled fluorescently, can detect hard electrophilic aldehydes only by forming unstable imine derivatives. In this study, we aimed to develop novel fluorescently labeled TRs that detect both soft and hard electrophilic RMs and form stable ring structures with aldehydes. We designed four dansylated TRs based on cysteine, which has both soft and hard nucleophilic groups. To evaluate the reactivity of the TRs, we incubated them with several substrates and found that one of the TRs (CysGlu-Dan) detected all the soft and hard electrophilic RMs. We also examined the inhibition potential of each TR for seven major CYPs involved in drug metabolism and found that CysGlu-Dan showed an inhibitory profile similar to that of dGSH. In conclusion, CysGlu-Dan can be used to evaluate the risk of RMs in drug discovery.",

keywords = "Drug toxicity, Fluorescent labeling, Reactive metabolite, Risk assessment, Trapping reagent",

author = "Chikako Shibazaki and Tomoyuki Ohe and Kyoko Takahashi and Shigeo Nakamura and Tadahiko Mashino",

note = "Funding Information: This research was supported by the Platform Project for Supporting Drug Discovery and Life Science Research (Basis for Supporting Innovative Drug Discovery and Life Science Research) from AMED [Grant JP19am0101089 ]; JSPS KAKENHI [Grant 16K08379 ]; the Keio University Doctoral Student Grant-in-Aid Program 2019; the Keio University Faculty of Pharmacy Naomi Hoshino Memorial Grant-in-Aid Program; and a special grant generously provided by the Hoansha Foundation . Publisher Copyright: {\textcopyright} 2021 The Japanese Society for the Study of Xenobiotics",

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doi = "10.1016/j.dmpk.2021.100386",

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AU - Shibazaki, Chikako

AU - Ohe, Tomoyuki

AU - Takahashi, Kyoko

AU - Nakamura, Shigeo

AU - Mashino, Tadahiko

N1 - Funding Information: This research was supported by the Platform Project for Supporting Drug Discovery and Life Science Research (Basis for Supporting Innovative Drug Discovery and Life Science Research) from AMED [Grant JP19am0101089 ]; JSPS KAKENHI [Grant 16K08379 ]; the Keio University Doctoral Student Grant-in-Aid Program 2019; the Keio University Faculty of Pharmacy Naomi Hoshino Memorial Grant-in-Aid Program; and a special grant generously provided by the Hoansha Foundation . Publisher Copyright: © 2021 The Japanese Society for the Study of Xenobiotics

PY - 2021/8

Y1 - 2021/8

N2 - Trapping assays are conducted at lead optimization stages to detect reactive metabolites (RMs) that can contribute to drug toxicity. The commonly used dansyl glutathione (dGSH) provides a sensitive analysis owing to the fluorescent label, however, it captures only soft electrophilic RMs. TRs for hard electrophilic RMs, few of which are labeled fluorescently, can detect hard electrophilic aldehydes only by forming unstable imine derivatives. In this study, we aimed to develop novel fluorescently labeled TRs that detect both soft and hard electrophilic RMs and form stable ring structures with aldehydes. We designed four dansylated TRs based on cysteine, which has both soft and hard nucleophilic groups. To evaluate the reactivity of the TRs, we incubated them with several substrates and found that one of the TRs (CysGlu-Dan) detected all the soft and hard electrophilic RMs. We also examined the inhibition potential of each TR for seven major CYPs involved in drug metabolism and found that CysGlu-Dan showed an inhibitory profile similar to that of dGSH. In conclusion, CysGlu-Dan can be used to evaluate the risk of RMs in drug discovery.

AB - Trapping assays are conducted at lead optimization stages to detect reactive metabolites (RMs) that can contribute to drug toxicity. The commonly used dansyl glutathione (dGSH) provides a sensitive analysis owing to the fluorescent label, however, it captures only soft electrophilic RMs. TRs for hard electrophilic RMs, few of which are labeled fluorescently, can detect hard electrophilic aldehydes only by forming unstable imine derivatives. In this study, we aimed to develop novel fluorescently labeled TRs that detect both soft and hard electrophilic RMs and form stable ring structures with aldehydes. We designed four dansylated TRs based on cysteine, which has both soft and hard nucleophilic groups. To evaluate the reactivity of the TRs, we incubated them with several substrates and found that one of the TRs (CysGlu-Dan) detected all the soft and hard electrophilic RMs. We also examined the inhibition potential of each TR for seven major CYPs involved in drug metabolism and found that CysGlu-Dan showed an inhibitory profile similar to that of dGSH. In conclusion, CysGlu-Dan can be used to evaluate the risk of RMs in drug discovery.

KW - Drug toxicity

KW - Fluorescent labeling

KW - Reactive metabolite

KW - Risk assessment

KW - Trapping reagent

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