Exposure to genotoxic carcinogens leads to increased expression of the GADD45a gene in mammalian cells. This signature of genotoxic hazard has previously been exploited in the GreenScreen HC assay, in which GADD45a expression is linked to green fluorescent protein (GFP) expression in the human TK6 lymphoblastoid cell line. This article describes the development and validation of an alternative assay ("BlueScreen HC"), in which expression is linked to Gaussia luciferase (GLuc) expression, yielding a luminescent reporter, the preferred optical output in high-throughput screening. The coelentrazine substrate of GLuc is relatively unstable, and a new buffer is reported that improves its stability. A more sensitive method is demonstrated for the measurement of cell densities in the assay, using the fluorescent cyanine dye thiazole orange. A protocol amendment also allows the assessment of pro-genotoxicity using S9 liver extracts. Compounds from the European Centre for the Validation of Alternative Methods (ECVAM) recommended list for the assessment of new or improved genotoxicity assays were evaluated with and without S9 in the new assay. The new GLuc assay was as effective as the GFP assay in producing positive results for all classes of genotoxic carcinogen and negative results for all nongenotoxins tested.
A recent ECVAM workshop considered how to reduce falsely predictive positive results when undertaking in vitro genotoxicity testing, and thus to avoid unnecessary follow-up with tests involving animals. As it was anticipated that modified versions of existing assays as well as new assays might contribute to a solution, an expert panel was asked to identify a list of chemicals that could be used in the evaluation of such assays. Three categories of test chemicals were chosen comprising a total of 62 compounds. This paper provides test results for these chemicals using the GreenScreen HC assay. All tests were carried out in triplicate, by multiple operators, with and without S9, using invariant protocols. Group 1 chemicals should be detected as positive in in vitro mammalian cell genotoxicity tests: 18/20 (90%) were reproducibly positive in GreenScreen HC. Group 2 chemicals should give negative results in in vitro genotoxicity tests: 22/23 (96%) were reproducibly negative in GreenScreen HC. Overall concordance for Groups 1 and 2 is 93%. Group 3 chemicals should give negative results in in vitro mammalian cell genotoxicity tests, but have been reported to induce chromosomal aberrations or Tk mutations in mouse lymphoma cells, often at high concentrations or at high levels of cytotoxicity: 13/17 (76%) were reproducibly negative in GreenScreen HC. Of the four positive compounds in Group 3, p-nitrophenol was only positive at the top dose (10mM), 2,4-DCP is an in vivo genotoxin, and two chemicals are antioxidant compounds that may be acting as pro-oxidants in the hyperoxic conditions of cell culture. Overall, these predictive figures are similar to those from other studies with the GreenScreen HC assay and confirm its high specificity, which in turn minimizes the generation of falsely predictive positive results.
Genotoxicity can be assessed by monitoring expression of a GADD45a-GFP reporter in the human lymphoblastoid cell line TK6. A flow cytometric method has been developed to effectively distinguish GFP fluorescence from coloured and fluorescent test samples as well from the S9 liver extracts used to generate metabolites from pro-genotoxins. The method includes the use of propidium iodide exclusion for the determination of cellular viability. This paper describes the method development, the derivation of decision thresholds for the identification of genotoxins using the method, and presents data from a 56-compound validation study of the method. The results illustrate that the method permitted the detection of the majority of pro-genotoxins tested and, importantly, the high specificity of the GADD45a-GFP assay was maintained.
The micronucleus (MN) assay is widely used as part of a battery of tests applied to evaluate the genotoxic potential of chemicals, including new food additives and novel food ingredients. Micronucleus assays typically utilise homogenous in vitro cell lines which poorly recapitulate the physiology, biochemistry and genomic events in the gut, the site of first contact for ingested materials. Here we have adapted and validated the MN endpoint assay protocol for use with complex 3D reconstructed intestinal microtissues; we have named this new protocol the reconstructed intestine micronucleus cytome (RICyt) assay. Our data suggest the commercial 3D microtissues replicate the physiological, biochemical and genomic responses of native human small intestine to exogenous compounds. Tissues were shown to maintain log-phase proliferation throughout the period of exposure and expressed low background MN. Analysis using the RICyt assay protocol revealed the presence of diverse cell types and nuclear anomalies (cytome) in addition to MN, indicating evidence for comprehensive DNA damage and mode(s) of cell death reported by the assay. The assay correctly identified and discriminated direct-acting clastogen, aneugen and clastogen requiring exogenous metabolic activation, and a non-genotoxic chemical. We are confident that the genotoxic response in the 3D microtissues more closely resembles the native tissues due to the inherent tissue architecture, surface area, barrier effects and tissue matrix interactions. This proof-of-concept study highlights the RICyt MN cytome assay in 3D reconstructed intestinal microtissues is a promising tool for applications in predictive toxicology.
The aim of the present study was to evaluate the compatibility of reconstructed 3D human small intestinal microtissues to perform the in vitro comet assay. The comet assay is a common follow-up genotoxicity test to confirm or supplement other genotoxicity data. Technically, it can be performed utilising a range of in vitro and in vivo assay systems. Here, we have developed a new reconstructed human intestinal comet (RICom) assay protocol for the assessment of orally ingested materials. The human intestine is a major site of food digestion and adsorption, first-pass metabolism as well as an early site of toxicant first contact and thus is a key site for evaluation. Reconstructed intestinal tissues were dosed with eight test chemicals: ethyl methanesulfonate (EMS), ethyl nitrosourea (ENU), phenformin hydrochloride (Phen HCl), benzo[a]pyrene (BaP), 1,2-dimethylhydrazine hydrochloride (DMH), potassium bromate (KBr), glycidamide (GA) and etoposide (Etop) over a span of 48 hours. The RICom assay correctly identified the genotoxicity of EMS, ENU, KBr and GA. Phen HCl, a known non-genotoxin, did not induce DNA damage in the 3D reconstructed intestinal tissues whilst showing high cytotoxicity as assessed by the assay. The 3D reconstructed intestinal tissues possess sufficient metabolic competency for the successful detection of genotoxicity elicited by BaP, without the use of exogenous metabolic system. In contrast, DMH, a chemical that requires liver metabolism to exert genotoxicity, did not induce detectable DNA damage in the 3D reconstructed intestinal tissue system. The genotoxicity of Etop, which is dependent on cellular proliferation, was also undetectable. These results suggest the RICom assay protocol is a promising tool for further investigation and safety assessment of novel ingested materials. We recommend that further work will broaden the scope of the 3D reconstructed intestinal tissue comet assay and facilitate broader analyses of genotoxic compounds having more varied mode of actions.
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