Transgenic nmice with a A shuttle vector containing a lacI target gene were generated for use as a shortterm, in vivo mutagenesis assay. The gene is recovered from the treated mice by exposing mouse genomic DNA to in vitro packaging extracts and plating the rescued phage on agar plates containing 5-bromo-4-chloro-3-indolyl (3-D-galactopyranoside (X-Gal). Phage with mutations in the lacl gene form blue plaques, whereas phage with a nonmutated lacl form colorless plaques. Spontaneous background mutant rates using this system range from 0.6 x 10-S to 1.7 x i0-0, depending upon tissue analyzed, with germ cells exhibiting less than one-third the background rate of somatic tissue. Treatment of the miceor cyclophosphamide caused an induction of mutations over background. Recovery of the lacI target for sequence analysis was performed by genetic excision of a plasmid from the phage using partial filamentous phage origins. The predominant mutations identified from untreated and treated populations were base substitutions. Although it has been shown by others that 70% of all spontaneous mutations within the laI gene, when replicated in Escherichia cohi, occur at a hot spot located at bases 620-632, only 1 of 21 spontaneous mutations has been identified in this region in the transgenic mouse system. In addition, 5 of 9 spontaneous transitions analyzed occur at CpG dinucleotides, whereas no transition mutations were identified at the prokaryotic deamination hot spots occurring at dcm sites (CCA/TGG) within the WaI gene. For EtNU, approximately equal amounts of transitions and transversions were observed, contrasting with B[a]P-induced mutations, in which only transversions were obtained. In addition, B[a]P mutagenesis showed a predominance ofmutations (81 %) involving cytosines and/or guanines, consistent with its known mode of action. The discovery of a spontaneous mutation spectrum different from that of bacterial assays, coupled with the concordance of EtNU and B[a]P base mutations with the known mechanisms of activity for these mutagens, suggests that this transgenic system will be useful as a short-term, in vivo system for mutagen assessment and analysis of mechanisms leading to mutations.The lacd gene has been used extensively as a target for the identification and analysis of spontaneous and induced mutations, due in part to the ease of using a calorimetric assay to rapidly screen for mutations. Genetic and sequence analysis of spontaneous and induced mutations detected in several systems utilizing lacd (1-5) has resulted in an extensive accumulation of data regarding the sequence specificity of spontaneous and induced mutations in lacd, which can be of considerable comparative value through the use of the lacd target gene in whole animal assay systems.To combine the cost-saving aspects of short-term assays with the predictive power of whole animal assays, we previously described the development of a system that depends upon efficient recovery of a A phage shuttle vector from transgenic mouse genomic DNA thro...
A short term, in vivo mutagenesis assay has been developed utilizing a lacl target gene contained within a lambda ZAP shuttle vector which has been incorporated into transgenic mice. Following chemical exposure, the target gene was recovered from mouse genomic DNA by mixing the DNA with in vitro lambda phage packaging extract. Mutations within the lacl target were identified by infecting host E. coli with the packaged phage and plating on indicator plates containing Xgal. Phage plaques with mutations in the lacl appeared blue, while intact phage were colorless. The ratio of blue plaques to colorless plaques is a measure of the mutagenicity of the compound. This system was used to obtain significant induction (up to 74-fold) over background levels for a variety of compounds, including N-ethyl-N-nitrosourea, benzo(a)pyrene (BaP), cyclophosphamide, and methylnitrosourea. Sequence analysis of selected mutant clones derived from this system was accomplished through the use of partial filamentous phage origins which allow rapid transfer of the target gene from phage to plasmid. Sequence analysis of spontaneous mutants derived from the mice primarily found of base substitutions, differing markedly from the previous data for spontaneous mutations in lacl derived from E. coli, where the preponderance of mutations were found at a single site, a repeated tetramer sequence. Upon sequence analysis of BaP derived base substitutions, only transversions were obtained, consistent with the known mechanism of BaP mutagenesis. Use of the well-characterized lacl gene in transgenic mice should allow for extrapolation of the extensive pool of in vitro data to whole animals, as well as provide insight into the tissue specific effects of mutagenic compounds.
Transgenic mouse lineages were established that carry the normal (M) or mutant (Z) alleles of the human alpha 1-antitrypsin (alpha 1-Pi) gene. All of the alpha 1-Pi transgenic mice expressed the human protein in the liver, cartilage, gut, kidneys, lymphoid macrophages, and thymus. The human M-allele protein was secreted normally into the serum. However, the human Z-allele protein accumulated in several cell types, but particularly in hepatocytes, and was found in serum in tenfold lower concentrations than the M-allele protein. Mice in one lineage carrying the mutant Z allele expressed high levels of human alpha 1-Pi RNA and displayed significant runting (50% of normal weight) in the neonatal period. This lineage was found to have alpha 1-Pi-induced liver pathology in the neonatal period, concomitant with the accumulation of human Z protein in diastase-resistant cytoplasmic globules that could be revealed in the Periodic acid-Schiff reaction (PAS). The phenotype of mice in the strain expressing high levels of the Z allele is remarkably similar to human neonatal hepatitis, and this strain may prove to be a useful animal model for studying this disease.
Transgenic mice suitable for the in vivo assay of suspected mutagens at the chromosome level have been constructed by stable integration of a lambda phage shuttle vector. The shuttle vector, which contains a beta-galactosidase (beta-gal) target gene, can be rescued from genomic DNA with in vitro packaging extracts. Mutations in the target gene are detected by a change in lambda phage plaque color on indicator agar plates. Initial rescue efficiencies of less than 1 plaque forming unit (pfu)/100 micrograms of genomic DNA were too low for mutation analysis. We determined the cause of the low rescue efficiencies by examining primary fibroblast cultures prepared from fetuses of lambda transgenic animals. The rescue efficiency of 5-azacytidine-treated cells increased 50-fold over non-treated controls indicating that methylation was inhibiting rescue. The inhibitory role of methylation was supported by the observation that mcr deficient E. coli plating strains and mcr deficient lambda packaging extracts further improved lambda rescue efficiency. Present rescue efficiencies of greater than 2000 pfu/copy/micrograms of genomic DNA represent a 100,000-fold improvement over initial rescue efficiencies, permitting quantitative mutational analysis. The background mutagenesis rate was estimated at 1 x 10(-5) in two separate lineages. Following treatment with the mutagen N-ethyl-N-nitrosourea (EtNU), a dose dependent increase in the mutation rate was observed in DNA isolated from mouse spleen, with significant induction also observed in mouse testes DNA.
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