Abstract
In vivo transposon mutagenesis, coupled with deep sequencing, enables large-scale genome-wide mutant screens for genes essential in different growth conditions. We analyzed six large-scale studies performed on haploid strains of three yeast species (Saccharomyces cerevisiae, Schizosaccaromyces pombe, and Candida albicans), each mutagenized with two of three different heterologous transposons (AcDs, Hermes, and PiggyBac). Using a machine-learning approach, we evaluated the ability of the data to predict gene essentiality. Important data features included sufficient numbers and distribution of independent insertion events. All transposons showed some bias in insertion site preference because of jackpot events, and preferences for specific insertion sequences and short-distance vs long-distance insertions. For PiggyBac, a stringent target sequence limited the ability to predict essentiality in genes with few or no target sequences. The machine learning approach also robustly predicted gene function in less well-studied species by leveraging cross-species orthologs. Finally, comparisons of isogenic diploid versus haploid S. cerevisiae isolates identified several genes that are haplo-insufficient, while most essential genes, as expected, were recessive. We provide recommendations for the choice of transposons and the inference of gene essentiality in genome-wide studies of eukaryotic haploid microbes such as yeasts, including species that have been less amenable to classical genetic studies.
Highlights
Work with model yeasts such as Saccharomyces cerevisiae and Schizosaccharomyces pombe has pioneered the combination of genotype/phenotype comparisons at a genomic scale
The number of transposition events detected in the different studies varied considerably, from over 500,000 unique insertion sites and 84 million total reads for the C. albicans AcDs (CaAcDs), to as few as 37,500 unique insertions and 6.1 million reads in the S. pombe PiggyBac (SpPB) data set (Table 2)
We suggest a number of metrics for the inference of gene essentiality using in vivo transposon mutagenesis studies in yeasts, including those with little available genetic data
Summary
Work with model yeasts such as Saccharomyces cerevisiae and Schizosaccharomyces pombe has pioneered the combination of genotype/phenotype comparisons at a genomic scale. Work on these yeasts, which have had genome sequences available for more than 20 years (Goffeau et al 1996; Wood et al 2002), along with facile gene replacement protocols, has relied heavily on comprehensive collections of deletion mutants (Giaever et al 2002; Kim et al 2010) for high-throughput dissection of specific genotypes, as well as for genetic interactions with drugs (reviewed in (Lehár et al 2008) and gene–gene interactions through systematic analysis of double and triple mutant analysis (e.g., Reguly et al 2006; Kuzmin et al 2018). The transposon is usually engineered for facile selection of excision and/or reinsertion events, allowing detection and enrichment of these rare events
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