Background <p>Overcoming species differences in metabolism between humans and animals remains a critical challenge in toxicological studies. Rat liver S9 fraction has long been the gold standard for exogenous metabolic activation in in vitro genotoxicity tests. Experiences with human S9 or human primary hepatocytes have suggested that the human materials are unsuitable for standardized testing due to high variability. Nevertheless, there is growing interest in genotoxicity evaluation using metabolic systems that more closely mimic human physiology.</p> Results <p>We developed an in-cell ELISA system to measure γH2AX as a DNA damage marker in stable human hepatocytes (γH2AX-SHE). HepaSH cells are consistently available human hepatocytes that stably express a range of metabolic enzymes and drug transporters in vitro. Due to their highly differentiated and non-proliferative nature, conventional genotoxicity endpoints such as micronuclei formation, chromosomal aberrations, or mutant colony assays are not applicable. We used γH2AX, a sensitive DNA damage marker, in this assay system. Indirect mutagens including benzo(a)pyrene, aristolochic acid, and 2-Amino-1-methyl-6-phenylimidazo(4,5-b)pyridine induced dose-dependent increases in γH2AX across all three HepaSH strains. Time-course analysis following benzo(a)pyrene exposure indicated that a treatment duration of 16 hours or longer was necessary to detect genotoxic responses. Prolonged exposure for 48 hours resulted in extensive cell death, which may interfere with γH2AX quantification.</p> Conclusions <p>We demonstrated that γH2AX-SHE can serve as a valuable tool for detecting DNA damage under conditions that mimic human metabolic activity. Based on the findings in this study, we recommend the following assay conditions for γH2AX-SHE: a 24-hour treatment period, a DMSO concentration not exceeding 1%, and careful interpretation of positive responses observed at highly cytotoxic doses - defined as approximately less than 60% cell survival – as these may lack biological relevance.</p>

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Development of a DNA damage assay system using stable human hepatocytes

  • Masayuki Mishima,
  • Kazuki Izawa,
  • Masataka Tsuda,
  • Yuichiro Higuchi,
  • Shotaro Uehara,
  • Hiroshi Suemizu,
  • Kei-Ichi Sugiyama

摘要

Background

Overcoming species differences in metabolism between humans and animals remains a critical challenge in toxicological studies. Rat liver S9 fraction has long been the gold standard for exogenous metabolic activation in in vitro genotoxicity tests. Experiences with human S9 or human primary hepatocytes have suggested that the human materials are unsuitable for standardized testing due to high variability. Nevertheless, there is growing interest in genotoxicity evaluation using metabolic systems that more closely mimic human physiology.

Results

We developed an in-cell ELISA system to measure γH2AX as a DNA damage marker in stable human hepatocytes (γH2AX-SHE). HepaSH cells are consistently available human hepatocytes that stably express a range of metabolic enzymes and drug transporters in vitro. Due to their highly differentiated and non-proliferative nature, conventional genotoxicity endpoints such as micronuclei formation, chromosomal aberrations, or mutant colony assays are not applicable. We used γH2AX, a sensitive DNA damage marker, in this assay system. Indirect mutagens including benzo(a)pyrene, aristolochic acid, and 2-Amino-1-methyl-6-phenylimidazo(4,5-b)pyridine induced dose-dependent increases in γH2AX across all three HepaSH strains. Time-course analysis following benzo(a)pyrene exposure indicated that a treatment duration of 16 hours or longer was necessary to detect genotoxic responses. Prolonged exposure for 48 hours resulted in extensive cell death, which may interfere with γH2AX quantification.

Conclusions

We demonstrated that γH2AX-SHE can serve as a valuable tool for detecting DNA damage under conditions that mimic human metabolic activity. Based on the findings in this study, we recommend the following assay conditions for γH2AX-SHE: a 24-hour treatment period, a DMSO concentration not exceeding 1%, and careful interpretation of positive responses observed at highly cytotoxic doses - defined as approximately less than 60% cell survival – as these may lack biological relevance.