Human iPSC-derived renal organoids engineered to report oxidative stress can predict drug-induced toxicity

Melanie Lawrence; Mona Elhendawi; Michaela Morlock; Weijia Liu; Liu S; Anwar Palakkan; Lisa F Seidl; Peter Hohenstein; Anna-Karin Sjogren; Jamie A Davies

doi:10.1016/j.isci.2022.103884

Human iPSC-derived renal organoids engineered to report oxidative stress can predict drug-induced toxicity

Melanie Lawrence, Mona Elhendawi, Michaela Morlock, Weijia Liu, Liu S, Anwar Palakkan, Lisa F Seidl, Peter Hohenstein, Anna-Karin Sjogren, Jamie A Davies

Research output: Contribution to journal › Article › peer-review

Abstract

Advances in regenerative medicine have led to the construction of many types of organoids, which reproduce important aspects of endogenous organs but may be limited or disorganized in nature. While their usefulness for restoring function remains unclear, they have undoubted usefulness in research, diagnostics, and toxicology. In toxicology, there is an urgent need for better models for human kidneys. We used human iPS-cell (hiPSC)-derived renal organoids to identify HMOX1 as a useful marker of toxic stress via the oxidative stress pathway, and then constructed an HMOX1 reporter in hiPSCs. We used two forms of hiPSC-derived HMOX1-reporter renal organoids to probe their ability to detect nephrotoxicants in a panel of blind-coded compounds. Our results highlight the potential usefulness, and some limitations, of HMOX1-reporter renal organoids as screening tools. The results may guide development of similar stress-reporting organoid assays for other stem-cell-derived organs and tissues.

Original language	English
Article number	103884
Journal	iScience
Volume	25
Issue number	3
Early online date	18 Mar 2022
DOIs	https://doi.org/10.1016/j.isci.2022.103884
Publication status	Published - 18 Mar 2022

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title = "Human iPSC-derived renal organoids engineered to report oxidative stress can predict drug-induced toxicity",

abstract = "Advances in regenerative medicine have led to the construction of many types of organoids, which reproduce important aspects of endogenous organs but may be limited or disorganized in nature. While their usefulness for restoring function remains unclear, they have undoubted usefulness in research, diagnostics, and toxicology. In toxicology, there is an urgent need for better models for human kidneys. We used human iPS-cell (hiPSC)-derived renal organoids to identify HMOX1 as a useful marker of toxic stress via the oxidative stress pathway, and then constructed an HMOX1 reporter in hiPSCs. We used two forms of hiPSC-derived HMOX1-reporter renal organoids to probe their ability to detect nephrotoxicants in a panel of blind-coded compounds. Our results highlight the potential usefulness, and some limitations, of HMOX1-reporter renal organoids as screening tools. The results may guide development of similar stress-reporting organoid assays for other stem-cell-derived organs and tissues.",

author = "Melanie Lawrence and Mona Elhendawi and Michaela Morlock and Weijia Liu and Liu S and Anwar Palakkan and Seidl, \{Lisa F\} and Peter Hohenstein and Anna-Karin Sjogren and Davies, \{Jamie A\}",

note = "Funding Information: This work was supported by the Medical Research Council (MRC) grants MR/K010735/1 , MR/R026483/1 , Kidney Research UK grant RP\_002\_20160223 , The University of Edinburgh ISSF3 grant ( IS30R35 ) and the Biotechnology and Biological Sciences Research Council (BBSRC; grant number BB/P013732/1 ). ME was supported by a scholarship from the Egyptian Ministry of Higher Education and Scientific Research, Cultural Affairs and Missions sector. This research was funded in whole, or in part, by the Wellcome Trust [Grant number IS30R35 ]. For the purpose of open access, the author has applied a CC BY public copyright license to any Author Accepted Manuscript version arising from this submission”. Publisher Copyright: {\textcopyright} 2022 The Author(s)",

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AU - Lawrence, Melanie

AU - Elhendawi, Mona

AU - Morlock, Michaela

AU - Liu, Weijia

AU - S, Liu

AU - Palakkan, Anwar

AU - Seidl, Lisa F

AU - Hohenstein, Peter

AU - Sjogren, Anna-Karin

AU - Davies, Jamie A

N1 - Funding Information: This work was supported by the Medical Research Council (MRC) grants MR/K010735/1 , MR/R026483/1 , Kidney Research UK grant RP_002_20160223 , The University of Edinburgh ISSF3 grant ( IS30R35 ) and the Biotechnology and Biological Sciences Research Council (BBSRC; grant number BB/P013732/1 ). ME was supported by a scholarship from the Egyptian Ministry of Higher Education and Scientific Research, Cultural Affairs and Missions sector. This research was funded in whole, or in part, by the Wellcome Trust [Grant number IS30R35 ]. For the purpose of open access, the author has applied a CC BY public copyright license to any Author Accepted Manuscript version arising from this submission”. Publisher Copyright: © 2022 The Author(s)

PY - 2022/3/18

Y1 - 2022/3/18

N2 - Advances in regenerative medicine have led to the construction of many types of organoids, which reproduce important aspects of endogenous organs but may be limited or disorganized in nature. While their usefulness for restoring function remains unclear, they have undoubted usefulness in research, diagnostics, and toxicology. In toxicology, there is an urgent need for better models for human kidneys. We used human iPS-cell (hiPSC)-derived renal organoids to identify HMOX1 as a useful marker of toxic stress via the oxidative stress pathway, and then constructed an HMOX1 reporter in hiPSCs. We used two forms of hiPSC-derived HMOX1-reporter renal organoids to probe their ability to detect nephrotoxicants in a panel of blind-coded compounds. Our results highlight the potential usefulness, and some limitations, of HMOX1-reporter renal organoids as screening tools. The results may guide development of similar stress-reporting organoid assays for other stem-cell-derived organs and tissues.

AB - Advances in regenerative medicine have led to the construction of many types of organoids, which reproduce important aspects of endogenous organs but may be limited or disorganized in nature. While their usefulness for restoring function remains unclear, they have undoubted usefulness in research, diagnostics, and toxicology. In toxicology, there is an urgent need for better models for human kidneys. We used human iPS-cell (hiPSC)-derived renal organoids to identify HMOX1 as a useful marker of toxic stress via the oxidative stress pathway, and then constructed an HMOX1 reporter in hiPSCs. We used two forms of hiPSC-derived HMOX1-reporter renal organoids to probe their ability to detect nephrotoxicants in a panel of blind-coded compounds. Our results highlight the potential usefulness, and some limitations, of HMOX1-reporter renal organoids as screening tools. The results may guide development of similar stress-reporting organoid assays for other stem-cell-derived organs and tissues.

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Human iPSC-derived renal organoids engineered to report oxidative stress can predict drug-induced toxicity

Abstract

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