A refined protocol for conducting the low pH 6.7 Syrian hamster embryo (SHE) cell transformation assay

Miniaturization of cytotoxicity tests for concentration range-finding studies prior to conducting the pH 6.7 Syrian hamster embryo cell-transformation assay

The Syrian hamster embryo (SHE) cell-transformation assay (SHE assay) is a promising alternative method to animal testing for the identification of potential carcinogens in vitro. Prior to conducting the SHE assay the appropriate concentration range for each test chemical must be established, with a maximum concentration causing approximately 50% cytotoxicity. Concentration range-finding is done in separate experiments, which are similar to the final SHE assay but with less replicates and more concentrations. Here we present an alternative for the cytotoxicity testing by miniaturization of the test procedure by use of 24-well plates and surpluses from feeder-cell preparations as target cells. In addition, we integrated the photometry-based neutral red (NR) assay. For validation of the assay, incubations with dimethyl sulf-oxide, p-phenylenediamine-2HCl, aniline, o-toluidine-HCl, 2,4-diaminotoluene, and 2-naphthylamine were carried out in the miniaturized approach and compared with the standard procedure in terms of calculating the relative plating efficiencies (RPEs). To directly compare both methods, concentrations that produced 50% cytotoxicity (IC50) were calculated. Excellent associations were observed between the number of colonies and NR uptake. For all test substances a concentration-dependent, concomitant decrease of NR uptake in the miniaturized approach and RPEs in the standard test was observed after a 7-day incubation. The results from both test setups showed a comparable order of magnitude and the IC50 values differed by a factor <2 (1.4-1.9), depending on the substance in question. Overall, the miniaturized approach should be considered an improved alternative for cytotoxicity testing in the SHE assay, as it saves valuable SHE cells and speeds-up the time, to obtain test results more rapidly.

Rodent cell transformation assays-a brief historical perspective

In vitro cell transformation is a process characterized by a series of progressive distinctive events that often emulate manifestations occurring in vivo and which are associated with neoplasia. Attendant cellular and sub-cellular alterations include, among others: cellular immortality, phenotypic changes, aneuploidy, genetic variability, cellular disarray, anchorage-independent growth, and tumorigenicity in vivo. Early chemically induced neoplastic transformation studies involved the use of normal diploid (Syrian) hamster embryo (SHE) cells and monitored the formation of morphologically altered colonies. Later investigations employed primarily two established mouse cell lines, i.e. the BALB/c 3T3 A31 cell line and the C3H 10T 1/2 cell line, and monitored the induction of morphologically aberrant foci. In either case, such transformed cellular clusters (colonies and foci) could induce tumors upon inoculation in vivo. Some subsequent noteworthy advancements using these systems included pH adjustments, metabolic supplementation, amplification of expression of formerly latent transformed foci, concurrent detection of mutagenesis and transformation, and use of a Bhas 42 cell line (v-Ha-ras transfected BALB/c 3T3 cells) to detect both tumor initiators and promoters. Over time, such transformation assay systems have been found useful in academic, industry and regulatory laboratories, generally for research purposes, but also occasionally as screening tools for potential chemical carcinogens. Nevertheless, to date, use of these assays for decision-making purposes in the regulatory arena remains elusive and will require comprehensive validation to gain universal acceptance.

Photo catalogue for the classification of cell colonies in the Syrian hamster embryo (SHE) cell transformation assay at pH 6.7

This catalogue is a display of Syrian hamster embryo (SHE) cell colony photos representative of the cell transformation assay (CTA) carried out at pH 6.7. It is intended as a visual aid for the identification and the scoring of cell colonies in the conduct of the assay. A proper training from experienced personnel together with the protocol reported in this issue and the present photo catalogue will support method transfer and consistency in the assay results.

ECVAM prevalidation study on in vitro cell transformation assays: general outline and conclusions of the study

The potential for a compound to induce carcinogenicity is a key consideration when ascertaining hazard and risk assessment of chemicals. Among the in vitro alternatives that have been developed for predicting carcinogenicity, in vitro cell transformation assays (CTAs) have been shown to involve a multistage process that closely models important stages of in vivo carcinogenesis and have the potential to detect both genotoxic and non-genotoxic carcinogens. These assays have been in use for decades and a substantial amount of data demonstrating their performance is available in the literature. However, for the standardised use of these assays for regulatory purposes, a formal evaluation of the assays, in particular focusing on development of standardised transferable protocols and further information on assay reproducibility, was considered important to serve as a basis for the drafting of generally accepted OECD test guidelines. To address this issue, a prevalidation study of the CTAs using the BALB/c 3T3 cell line, SHE cells at pH 6.7, and SHE cells at pH 7.0 was coordinated by the European Centre for the Validation of Alternative Methods (ECVAM) and focused on issues of standardisation of protocols, test method transferability and within- and between-laboratory reproducibility. The study resulted in the availability of standardised protocols that had undergone prevalidation [1,2]. The results of the ECVAM study demonstrated that for the BALB/c 3T3 method, some modifications to the protocol were needed to obtain reproducible results between laboratories, while the SHE pH 6.7 and the SHE pH 7.0 protocols are transferable between laboratories, and results are reproducible within- and between-laboratories. It is recommended that the BALB/c 3T3 and SHE protocols as instituted in this prevalidation study should be used in future applications of these respective transformation assays. To support their harmonised use and regulatory application, the development of an OECD test guideline for the SHE CTAs, based on the protocol published in this issue, is recommended. The development of an OECD test guideline for the BALB/c 3T3 CTA should likewise be further pursued upon the availability of additional supportive data and improvement of the statistical analysis.

Establishment of a Stable Cell Line Expressing Green Fluorescence Protein-fused Hypoxia Inducible Factor-1α for Assessment of Carcinogenicity of Chemical Toxicants

Hypoxia inducible factor 1α (HIF-1α) is a potential marker of carcicnogenesis since it is overexpresssed in many human cancers such as brain, breast, and uterus, and its role has implicated in tumor cell growth and metastasis. In this study, we established a stable cell line that express green fluorescence protein (GFP)-fused hypoxia inducible factor 1α (HIF-1α) and evaluated the potential use of this cell line for assessment of carcinogenicity of chemical toxicants. Western blot analysis as well as fluorescence measurements showed that protein-level of GFP-HIF-1α was significantly enhanced in a dose-dependent manner upon treatment of hypoxia mimicking agents such as dexferrioxamine and CoCl₂. Well-Known tumor promoters such as mitomycin and methyl methane-sulfonate. significantly induced the fluorescence intensity of GFP-HIF-1α, whereas the known negative controls such as o-anthranilic acid and benzethonium chloride, did not. These results indicate that HIF-1α could be a biological parameter for detection of tumor initiators/promoters and suggest that the GFP-HIF-1α cell line is a useful system for screening of carcinogenic toxicants.

Application of a two-stage Syrian hamster embryo cell transformation assay to cigarette smoke particulate matter

The induction of transformation in Syrian hamster embryo (SHE) cells is a multifactorial process, in comparison to endpoints induced in in vitro genotoxicity assays such as Ames, mouse lymphoma and cytogenetics [Y. Berwald, L. Sachs, In vitro cell transformation with chemical carcinogens, Nature (London) 200 (1963) 1182-1184]. Furthermore, a number of non-genotoxic carcinogens and promoters such as clofibrate and diethylhexylphthalate, have been positively identified in this assay, while giving false negative results in traditional genotoxicity assays [H. Yamasaki, J. Ashby, M. Bignami, W. Jongen, K. Linnainmaa, R.F. Newbold, G. Nguyen-Ba, S. Parodi, E. Rivedal, D. Schiffmann, J.W.I.M. Simons, P. Vasseur, Nongenotoxic carcinogens: development of detection methods based on mechanisms: a European project, Mutat. Res. 353 (1996) 47-63]. A high concordance between results obtained in this assay when compared with rodent carcinogenesis bioassays has also been noted [R.J. Isfort, G.A. Kerckaert, R.A. LeBoeuf, Comparison of the standard and reduced pH Syrian hamster embryo (SHE) in vitro cell transformation assays to predict the carcinogenic potential of chemicals, Mutat. Res. 356 (1996) 11-63]. Carcinogenesis is known to be a multistage process, with agents potentially acting at each stage. Specifically, mouse skin painting experiments established that tumour induction could be mechanistically divided into two distinct phases, termed initiation and promotion. Initiation, is defined as the stage at which a normal cell is converted to a latent tumour cell, followed by promotion where the latent tumour cell progresses to a tumour [W.F. Friedwald, P. Rous, The initiating and promoting elements in tumour production: analysis of the effects of tar, benzpyrene and methylcholanthrene on rabbit skin, J. Exp. Med. 80 (1944) 101-125]. A protocol for the pH 6.7 SHE transformation assay has been developed which allows separation of cell transformation process into two phases, potentially analogous to initiation and promotion in vivo. This allows chemicals found to be positive in the traditional SHE cell transformation assay to be further classified as initiators or promoters. Following validation with known initiators, benzo(a)pyrene and N-methyl-N'-nitro-N-nitrosoguanidine and promoters, 12-O-tetradecanoyl-phorbol-13-acetate and phenobarbitone, the two-stage model was applied to cigarette smoke particulates which was found to act both at the initiation and promotion stage of cell transformation.

Nonlinear response for neoplastic transformation following low doses of low let radiation

There are now several independent studies that indicate that the dose-response for the endpoint of radiation-induced neoplastic transformation in vitro is non-linear for low linear energy transfer (LET) radiation. At low doses (<10 cGy) the transformation frequency drops below that seen spontaneously. Importantly, this observation has been made using fluoroscopic energy x-rays, a commonly used modality in diagnostic radiology, the practice of which is responsible for the majority of radiation exposure to the general public. Since the transformation frequency is reduced over a large dose range (0.1 to 10cGy) it is likely that multiple mechanisms are involved and that the relative contribution of these may vary with dose. These include the killing of a subpopulation of cells prone to spontaneous transformation at the lowest doses, and the induction of DNA repair at somewhat higher doses. Protective effects of low doses of low LET radiation on other cancer-relevant endpoints in vitro and in vivo have also been observed by several independent laboratories. These observations strongly suggest that the linear-nonthreshold dose-response model is unlikely to apply to the induction of cancer by low doses of low LET radiation in humans.

The testing of chemicals in the Syrian hamster embryo (SHE) cell transformation assay for assessment of carcinogenic potential

The Syrian hamster embryo (SHE) cell transformation assay was used to test 28 chemical substances for their ability to induce morphologically transformed colonies. The purpose was to determine how well the assay method could be transferred from an experienced laboratory by including 18 chemicals previously evaluated and 10 new chemicals. Technical training was obtained in the experienced lab prior to testing. The assay was conducted at pH 6.7, a treatment period of 7 days was used, and single experiments were performed for each chemical. With this limited testing, 78% concordance with rodent bioassay results was obtained, and this high concordance would have increased if small, but statistically negative responses from single trials were overturned by positive data from repeat trials. Similarly, the results were highly concordant (90%) with the experienced lab results; only 2 chemical evaluations were discordant, and the use of repeat experiments would likely have eliminated these apparent disagreements. Thus, with appropriate training, the pH 6.7 SHE assay was successfully and reliably transferred.

Enhancement of the morphological transformation of Syrian hamster embryo (SHE) cells by reducing incubation time of the target cells

Syrian hamster embryo (SHE) cell transformation has been used for many years to study chemical carcinogenesis in vitro. It has been shown that this assay is probably the most predictive short-term test system for identifying rodent carcinogens. Although most of the operational difficulties encountered in the early stage of application of this assay have been overcome by culturing the SHE cells under slightly acidic conditions (pH 6.7), a relatively low level of induction of morphological transformation (MT) by known carcinogens still occurs for many cell isolates. In order to improve the response of this assay system to known carcinogens, the effect of incubation time of target SHE cells on the frequency of morphological transformation induced by benzo(a)pyrene (BaP) was investigated. It was shown that the morphological transformation frequency induced by BaP increased significantly (1.4-2.5-fold) when the incubation time of target cells was reduced from the usual 24h to less than 6h prior to seeding onto feeder layers. This improvement in sensitivity was consistent for different cell isolates. In addition, the enhanced response appeared to be a property of carcinogens because treatment with two non-carcinogens, l-ascorbic acid and 4-nitro-o-phenylenediamine, did not induce significant increases in the transformation frequency under the shortened incubation period for target cells. These results suggest that the response of the SHE cell transformation assay may be improved by optimizing the incubation time of the target SHE cells. In addition, the results of the present study provide further evidence to support the idea that morphological transformation of SHE cells results from a block of cellular differentiation of stem or stem-like cells.

The carcinogenic potential of extractable organic matter from urban airborne particles in Shanghai, China

The genotoxicity of extractable organic matter (EOM) from airborne particles in Shanghai has been determined using short-term bioassays. EOM samples were investigated using cell morphological transformation and two-stage model of mouse skin tumorigenicity assays to detect their carcinogenic activity. DNA adducts were detected using the 32P-postlabeling technique. The results showed that EOMs induced cell morphological transformation and played a role in tumor-initiating carcinogenesis. The EOMs of airborne particles from different districts of Shanghai had similar carcinogenic activity except the result of sample E (at downtown of Shanghai) was relatively high. The polycyclic aromatic hydrocarbon (PAH) fraction makes a major contribution to carcinogenic activity according to the results of cell morphological transformation assay. DNA adducts were also detected in skin, liver, and kidney of mouse after treatment with EOMs. It is suggested that the urban airborne particles in Shanghai, which show carcinogenic potential and genotoxic activity in our bioassays, may be responsible for the increased incidence of lung cancer in Shanghai in last few years.

The syrian hamster embryo (SHE) cell transformation assay: review of the methods and results

The Syrian hamster embryo (SHE) cell-transformation assay represents a short-term in vitro assay capable of predicting rodent carcinogenicity of chemicals with a high degree of concordance (LeBoeuf et al [1996]. Mutat Res 356: 85-127). The SHE assay models the earliest identifiable stage in carcinogenicity, morphological cell transformation. In contrast to other short-term in vitro assays, both genotoxic and epigenetic carcinogens are detected. The SHE assay, originally developed by Berwald and Sachs (J Natl Cancer Inst 35: 641-661) and modified as described by LeBoeuf and Kerckaert (Carcinogenesis 7: 1431-1440), was included in the International Life Sciences Institute, Health and Environmental Sciences Institute (ILSI/HESI). Alternative Carcinogenicity Testing (ACT) collaboration to provide additional information on the use of short-term in vitro tests in predicting carcinogenic potential. A total of 19 ILSI compounds have been tested in the SHE assay: 15 were tested for this project, whereas clofibrate, methapyrilene, reserpine, and Di(2-ethylhexyl)phalate (DEHP) were tested previously. Of the 3 noncarcinogenic compounds tested, 2 were negative in the SHE assay, whereas ampicillin was tested positive. The remaining 16 compounds tested were either known rodent carcinogens and/or human carcinogens. From this group, 15 tested positive in the SHE assay whereas phenacetin, a genotoxic carcinogen, was tested negative. Therefore, overall concordance between the SHE assay and rodent bioassay was 89% (17/19), whereas concordance with known or predicted human carcinogens was 37% (7/19). Based on these data, it is concluded that the SHE cell-transformation assay has utility for predicting the results of the rodent carcinogenesis bioassay but lacks the selectivity to distinguish between rodent and human carcinogens.