Continuous culture systems allow for the controlled growth of microorganisms over a long period of time. Here, we develop a novel test for mutagenicity that involves growing yeast in continuous culture systems exposed to low levels of mutagen for a period of weeks. In contrast, most microorganism-based tests for mutagenicity expose the potential mutagen to the biological reporter at a high concentration of mutagen for a short period of time. Our test improves upon the sensitivity of the well-established Ames test by at least 20-fold for each of two mutagens that act by different mechanisms (the intercalator ethidium bromide and alkylating agent methylmethane sulfonate). To conduct the tests, cultures were grown in small, inexpensive continuous culture systems in media containing (potential) mutagen, and the resulting mutagenicity of the added compound was assessed via two methods: a canavanine-based plate assay and whole genome sequencing. In the canavanine-based plate assay, we were able to detect a clear relationship between the amount of mutagen and the number of canavanine-resistant mutant colonies over a period of one to three weeks of exposure. Whole genome sequencing of yeast grown in continuous culture systems exposed to MMS demonstrated that quantification of mutations is possible by identifying the number of unique variants across each strain but with lower sensitivity than the plate-based assay. In conclusion, we propose yeast grown in continuous culture systems can provide an improved and more sensitive test for mutagenicity.
Continuous culture systems allow for the controlled growth of microorganisms over a long period of time. Here, we develop a novel test for mutagenicity that involves growing yeast in continuous culture systems exposed to low levels of mutagen for a period of approximately 20 days. In contrast, most microorganism-based tests for mutagenicity expose the potential mutagen to the biological reporter at a high concentration of mutagen for a short period of time. Our test improves upon the sensitivity of the well-established Ames test by at least 20-fold for each of two mutagens that act by different mechanisms (the intercalator ethidium bromide and alkylating agent methyl methanesulfonate). To conduct the tests, cultures were grown in small, inexpensive continuous culture systems in media containing (potential) mutagen, and the resulting mutagenicity of the added compound was assessed via two methods: a canavanine-based plate assay and whole genome sequencing. In the canavanine-based plate assay, we were able to detect a clear relationship between the amount of mutagen and the number of canavanine-resistant mutant colonies over a period of one to three weeks of exposure. Whole genome sequencing of yeast grown in continuous culture systems exposed to methyl methanesulfonate demonstrated that quantification of mutations is possible by identifying the number of unique variants across each strain. However, this method had lower sensitivity than the plate-based assay and failed to distinguish the different concentrations of mutagen. In conclusion, we propose that yeast grown in continuous culture systems can provide an improved and more sensitive test for mutagenicity.
The purpose of this protocol is to describe how to purify genomic (or chromosomal) DNA from yeast. Here, we use Saccharomyces cerevisiae strain DBY10418, though this protocol should apply to other yeast strains. This protocol is adapted from many other protocols (for example, see "Molecular genetic analysis of fission yeast Schizosaccharomyces pombe" by Sergio Moreno, Amar Klar, and Paul Nurse in Methods in Enzymology Volume 194, 1991, Pages 795-823, section: Preparing Schizosaccharomyces pombe Chromosomal DNA) but we made enough changes to those protocols that made it necessary to publish our own. We used the downstream DNA for whole genome sequencing with Illumina technology, but we anticipate the genomic DNA isolated in this manner can be used for other applications. This protocol uses Zymolyase to digest the yeast cell wall, SDS to lyse the cells, potassium acetate to precipitate proteins, and purifies the resulting genomic DNA via alcohol precipitations and RNase A digestion.
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