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Abstract
ENU mutagenesis is a powerful method for generating novel lines of mice that are informative with respect to both fundamental biological processes and human disease. Rapid developments in genomic technology have made the task of identifying causal mutations by positional cloning remarkably efficient. One limitation of this approach remains the mutation frequency achievable using standard treatment protocols, which currently generate approximately 1–2 sequence changes per megabase when optimized. In this study we used two strategies to attempt to increase the number of mutations induced by ENU treatment. One approach employed mice carrying a mutation in the DNA repair enzyme Msh6. The second strategy involved injection of ENU to successive generations of mice. To evaluate the number of ENU-induced mutations, single mice or pooled samples were analyzed using whole exome sequencing. The results showed that there is considerable variability in the induced mutation frequency using these approaches, but an overall increase in ENU-induced variants from one generation to another was observed. The analysis of the mice deficient for Msh6 also showed an increase in the ENU-induced variants compared to the wild-type ENU-treated mice. However, in both cases the increase in ENU-induced mutation frequency was modest.
Highlights
Forward genetic screens using N-ethyl-N-nitrosurea (ENU) as a chemical mutagen have revealed a wide spectrum of biological and disease processes [1]
In this report we describe the consequences of both the use of serial injection and the use of an mismatch repair (MMR)-deficient mouse line
In this study we demonstrate that serial administration of ENU to successive generations of mice increases the ENU-induced mutation frequency in both wild-type and Msh6+/-mice
Summary
Forward genetic screens using N-ethyl-N-nitrosurea (ENU) as a chemical mutagen have revealed a wide spectrum of biological and disease processes [1]. ENU causes DNA damage by transferring a methyl or ethyl group to the oxygen and nitrogen atoms of nucleotide bases (reviewed in [2] and [3]). The resulting base adducts tend to mispair during semi-conservative replication. If this is not corrected, the following round of replication will convert the mismatch to a point mutation. This method creates random mutations throughout the genome, which.
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