Direct separation of in vivo and in vitro am3 revertants in transgenic mice carrying the phiX174 am3, cs70 vector

Transgenic animal mutation models: a review of the models and how they function

In regulatory genetic toxicology, the endpoints available for routine study in vivo have been limited to looking at chromosomal damage or unscheduled DNA synthesis in a very limited number of tissues. With the development of transgenic gene mutation systems in rodents came the opportunity to investigate a new endpoint. The better-known λLacI and λLacZ are covered in some detail and the less well established models do receive mention with appropriate references for those wishing more information. Using a recommended experimental design it is now possible to look at the ability of a compound to induce gene mutation following in vivo exposure, in any tissue from which suitable DNA can be isolated.

In vivo mutation analysis using the ΦX174 transgenic mouse and comparisons with other transgenes and endogenous genes

The ΦX174 transgenic mouse was first developed as an in vivo Ames test, detecting base pair substitution (bps) at a single bp in a reversion assay. A forward mutational assay was also developed, which is a gain of function assay that also detects bps exclusively. Later work with both assays focused on establishing that a mutation was fixed in vivo using single-burst analysis: determining the number of mutant progeny virus from an electroporated cell by dividing the culture into aliquots before scoring mutants. We review results obtained from single-burst analysis, including testing the hypothesis that high mutant frequencies (MFs) of G:C to A:T mutation recovered by transgenic targets include significant numbers of unrepaired G:T mismatches. Comparison between the ΦX174 and lacI transgenes in mouse spleen indicates that the spontaneous bps mutation frequency per nucleotide (mf(n)) is not significantly lower for ΦX174 than for lacI; the response to ENU is also comparable. For the lacI transgene, the spontaneous bps mf(n) is highly age-dependent up to 12 weeks of age and the linear trend extrapolates at conception to a frequency close to the human bps mf(n) per generation of 1.7 × 10(-8). Unexpectedly, we found that the lacI somatic (spleen) bps mf(n) per cell division at early ages was estimated to be the same as for the human germ-line. The bps mf(n) in bone marrow for the gpt transgene is comparable to spleen for the lacI and ΦX174 transgenes. We conclude that the G:C to A:T transition is characteristic of spontaneous in vivo mutation and that the MFs measured in these transgenes at early ages reflect the expected accumulation of in vivo mutation typical of endogenous mammalian mutation rates. However, spontaneous and induced mf(n)s per nucleotide for the cII gene in spleen are 5-10 times higher than for these other transgenes.

Detailed review of transgenic rodent mutation assays

Induced chromosomal and gene mutations play a role in carcinogenesis and may be involved in the production of birth defects and other disease conditions. While it is widely accepted that in vivo mutation assays are more relevant to the human condition than are in vitro assays, our ability to evaluate mutagenesis in vivo in a broad range of tissues has historically been quite limited. The development of transgenic rodent (TGR) mutation models has given us the ability to detect, quantify, and sequence mutations in a range of somatic and germ cells. This document provides a comprehensive review of the TGR mutation assay literature and assesses the potential use of these assays in a regulatory context. The information is arranged as follows. (1) TGR mutagenicity models and their use for the analysis of gene and chromosomal mutation are fully described. (2) The principles underlying current OECD tests for the assessment of genotoxicity in vitro and in vivo, and also nontransgenic assays available for assessment of gene mutation, are described. (3) All available information pertaining to the conduct of TGR assays and important parameters of assay performance have been tabulated and analyzed. (4) The performance of TGR assays, both in isolation and as part of a battery of in vitro and in vivo short-term genotoxicity tests, in predicting carcinogenicity is described. (5) Recommendations are made regarding the experimental parameters for TGR assays, and the use of TGR assays in a regulatory context.

Incorporation of mammalian metabolism into mutagenicity testing

In the 1950's and 1960's it became obvious that many chemicals in daily use were mutagenic or carcinogenic, but there seemed to be little relation between the two activities. As scientists were debating the cause of this discrepancy, it was hypothesized that mammalian metabolism could form highly reactive intermediates from rather innocuous chemicals and that these intermediates could react with DNA and were mutagenic. This commentary presents the historical development of metabolic activation in mutagenicity tests, beginning with Udenfriend's hydroxylation system, which mimics aspects of mammalian metabolism in a purely chemical mixture, and extending through procedures that moved closer and closer to incorporating actual mammalian metabolism into the test systems. The stages include microsomal activation systems, host-mediated assays, incorporation of human P450 genes into the target cells or organisms, and detecting mutations in single cells in vivo. A recent development in this progression is the insertion of recoverable vectors containing mutational targets into the mammalian genome. Since the target genes of transgenic assays are in the genome, they are not only exposed to active metabolites, but they also undergo the same repair processes as endogenous genes of the mammalian genome.

Spontaneous mutant frequency and mutation spectrum for gene A of phiX174 grown in E. coli

The use of transgenic targets for measuring mutant frequencies in mammalian tissue requires an estimate of the mutant frequency that results from recovery of the transgene in bacterial recovery systems. In this study, we have determined the spontaneous mutant frequency, estimated the mutation rate, and ascertained the mutation spectrum for gene A of phiX174 grown in E. coli strain CQ2 from 156 small independent cultures. The mutant frequency of 12 of the 156 cultures was 17 +/- 1.0 x 10(-6) and the estimated mutation rate per gene replication was 7.4 +/- 2.3 x 10(-6). The mutant frequency and spectrum from E. coli were not significantly different from that of solvent-treated embryonic mouse cells in culture, 19 +/- 0.5 x 10(-6) (Valentine CR et al. [2002]: Environ Mol Mutagen 39:55-68), indicating that those spontaneous mutants were primarily derived from E. coli. The E. coli spectrum was heavily weighted toward two major target sites (hot spots), 4225A-->G (56%) and 4218G-->A or C (20%). Four new target sites and one new mutational event were recovered by the gene A forward assay. A mutant spectrum from an expanded phage stock was also determined to assess the effects of propagating the virus. This mutant frequency was higher (6 x 10(-4)), contained more double mutants (15% compared to 0.6%), and had a significantly different spectrum from the spectrum for independent cultures (fewer A:T-->G:C and G:C-->C:G changes and more G:C-->A:T; P < 0.002). The E. coli mutation spectrum will be useful for determining the origin of gene A mutation in tissues of phiX174 transgenic mice.

In vivo mutation in gene A of splenic lymphocytes from phiX174 transgenic mice

Single-burst analysis was applied to a forward assay for gene A mutation in splenic lymphocytes of phiX174 transgenic mice for the purpose of optimizing analytical parameters for identifying in vivo mutations. The effect of varying the cutoff value for an in vivo burst on induced mutant frequency, fold increase, and the significance of the difference between control and N-ethyl-N-nitrosourea (ENU)-treated mice was calculated by two different methods. The plating density was reduced to an average of less than 10 background mutant plaques per aliquot in order to separate in vitro bursts. The spectrum of mutations contributing < 60 plaques per aliquot from control animals was not significantly different from the control spectra from E. coli or transgenic phiX174 cells in culture. The mutant spectra from ENU-treated animals was highly different between mutant bursts of > 80 plaques per aliquot compared to mutations contributing < 60 plaques per aliquot (P < 0.000001), the former fitting the spectrum expected for ENU-induced mutations. The latter spectrum was also different from control animals and E. coli (P < 0.000001), suggesting the difference was caused by ex vivo mutation. With the mutations found in this study, the total number of reported target sites for gene A is now 33. The results support the interpretation that, in contrast to results for the lacI transgene, 100% of mutants isolated in gene A from control animals and cells were fixed in E. coli. We attribute the difference between the two genes to hot-spot sites for mutation in gene A and to a testable hypothesis that the mosaic plaque assay for the lacI transgene underestimates the frequency of ex vivo mutants.

The in vivo but not the in vitro am3 revertant frequencies increase linearly with increased ethylnitrosourea doses in spleen of mice transgenic for phiX174 am3, cs70 using the single burst assay

The am3 revertant frequencies (RF) in spleens from male mice transgenic for phiX174 am3, cs70 were analyzed 14 weeks after ethylnitrosourea (ENU) treatment, both by the single burst assay (SBA) and the mixed burst assay (MBA). The mean in vivo (burst size >30/assay plate) revertant frequency (MRF) for the vehicle control was 2.6x10(-7). The ENU induced in vivo RF were linear over the dose range 0-150mg/kg, (r(2)=0.999). The concomitant in (burst size <or=30/assay plate) was independent of dose (r(2)=0.216). The only viable revertants are base pair substitutions of the center base pair in the am3 nonsense (TAG) codon in the phiX174 lysis E gene. Sequenced revertants chosen randomly from in vitro plates and in vivo untreated control plates were A-->G transitions. Sequence analysis of in vivo revertants from ENU treated animals revealed revertants that were 17% A-->G transitions and 83% A-->T transversions, the latter being consistent with the reported A:T base pair alterations induced by ENU. No A-->C transitions were seen. This suggests the occurrence of an ENU-induced O(2) ET-dT lesion leading to a dT base mismatch. The observations in this report both confirm and validate the use of the SBA for distinguishing between in vivo mutations that are fixed in the animal and in vitro mutations that arise from other sources. The ability of the SBA to distinguish the in vivo from the in vitro origin of mutations has increased the specificity, sensitivity and utility of the phiX transgenic system.

Development of a microplate assay for the detection of single plaque-forming units of bacteriophage PhiX174 in crude lysates

Mice containing the PhiX174 am3 transgene can be used for measuring in vivo mutation; however, the single burst analysis method used for distinguishing in vivo mutations from mutations generated during sample processing is labor-intensive. A liquid microplate assay was developed that detects a single mutant plaque-forming unit (PFU) of PhiX174 bacterial virus in the presence of excess nonmutant virus. The assay is based on inhibiting reduction of the tetrazolium dye, MTS, by bacterial cells selective for mutant virus. The assay is performed with crude lysates of infected bacteria and is as accurate as scoring viral plaques on a bacterial lawn. This microplate assay may have application in increasing throughput of the single burst analysis of PhiX174 in transgenic mouse mutation assays.

Three origins of phiX174 am3 revertants in transgenic cell culture

Transgenic systems for measuring mammalian mutagenesis often use recoverable viral vectors. We hypothesize that mutations in these transgenic systems can arise from three different origins of DNA damage and replication errors and that these three origins of mutations (in vivo, ex vivo, and in vitro) can be differentiated in the PhiX174 am3, cs70 single burst assay (SBA) on the basis of burst size (BS). In vivo mutations are fixed in the animal, ex vivo mutations are fixed in bacterial cells during recovery of the phage, and in vitro revertants arise during the first replications of nonmutant phages under selective conditions. PX-2 cells, derived from a homozygous embryo of a PhiX174 transgenic mouse, were treated with vehicle or N-ethyl-N-nitrosourea (ENU). An algorithm was developed to estimate the BS that resulted in the highest induced revertant frequency; the estimate was 56. In vivo revertants were defined as having BS >55, ex vivo revertants as having a BS of 13-56, and in vitro revertants as having a BS of <14. The frequencies of in vivo revertants at 0, 100, and 200 mg/kg ENU were 0.06, 0.36, and 4.10 x 10(-6) (dose response, P = 0.004); ex vivo revertants were 0.36, 0.46, and 0.41 x 10(-6) (P = 0.37), and in vitro revertants were 0.39, 0.46, and 0.41 x 10(-6) (P = 0.55), respectively. These results show that only in vivo revertants reflect mutagen treatment. They also provide a basis for identifying PhiX174 am3 revertants induced in vivo and may increase the sensitivity of the assay for in vivo mutation.

Characterization of mutant spectra generated by a forward mutational assay for gene A of Phi X174 from ENU-treated transgenic mouse embryonic cell line PX-2

The sensitivity of in vivo transgenic mutation assays benefits from the sequencing of mutations, although the large number of possible mutations hinders high throughput sequencing. A forward mutational assay exists for Phi X174 that requires an altered, functional Phi X174 protein and therefore should have fewer targets (sense, base-pair substitutions) than forward assays that inactivate a protein. We investigated this assay to determine the number of targets and their suitability for detecting a known mutagen, N-ethyl-N-nitrosourea (ENU). We identified 25 target sites and 33 different mutations in Phi X174 gene A after sequencing over 350 spontaneous and ENU-induced mutants, mostly from mouse embryonic cell line PX-2 isolated from mice transgenic for Phi X174 am3, cs70 (line 54). All six types of base-pair substitution were represented among both the spontaneous and ENU-treated mutant spectra. The mutant spectra from cells treated with 200 and 400 microg/ml ENU were both highly different from the spontaneous spectrum (P < 0.000001) but not from each other. The dose trend was significant (P < 0.0001) for a linear regression of mutant frequencies (R(2) = 0.79), with a ninefold increase in mutant frequency at the 400 microg/ml dose. The spontaneous mutant frequency was 1.9 x 10(-5) and the spontaneous spectrum occurred at 11 target base pairs with 15 different mutations. Thirteen mutations at 12 targets were identified only from ENU-treated cells. Seven mutations had highly significant increases with ENU treatment (P < 0.0001) and 15 showed significant increases. The results suggest that the Phi X174 forward assay might be developed into a sensitive, inexpensive in vivo mutagenicity assay.