Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait
Isolation of mutants in populations of microorganisms has been a valuable tool in experimental genetics for decades. The main disadvantage, however, is the inability of isolating mutants in non-selectable polygenic traits. Most traits of organisms, however, are non-selectable and polygenic, including industrially important properties of microorganisms. The advent of powerful technologies for polygenic analysis of complex traits has allowed simultaneous identification of multiple causative mutations among many thousands of irrelevant mutations. We now show that this also applies to haploid strains of which the genome has been loaded with induced mutations so as to affect as many non-selectable, polygenic traits as possible. We have introduced about 900 mutations into single haploid yeast strains using multiple rounds of EMS mutagenesis, while maintaining the mating capacity required for genetic mapping. We screened the strains for defects in flavor production, an important non-selectable, polygenic trait in yeast alcoholic beverage production. A haploid strain with multiple induced mutations showing reduced ethyl acetate production in semi-anaerobic fermentation, was selected and the underlying quantitative trait loci (QTLs) were mapped using pooled-segregant whole-genome sequence analysis after crossing with an unrelated haploid strain. Reciprocal hemizygosity analysis and allele exchange identified PMA1 and CEM1 as causative mutant alleles and TPS1 as a causative genetic background allele. The case of CEM1 revealed that relevant mutations without observable effect in the haploid strain with multiple induced mutations (in this case due to defective mitochondria) can be identified by polygenic analysis as long as the mutations have an effect in part of the segregants (in this case those that regained fully functional mitochondria). Our results show that genomic saturation mutagenesis combined with complex trait polygenic analysis could be used successfully to identify causative alleles underlying many non-selectable, polygenic traits in small collections of haploid strains with multiple induced mutations.
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2016-04
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| Subjects: | genetic polymorphism, genetic markers, quantitative trait loci, mutagenesis, polimorfismo genético, marcadores genéticos, loci de rasgos cuantitativos, molecular biology, cell biology, genetics, microbiology, parasitology, virology, |
| Online Access: | https://hdl.handle.net/10568/72960 https://doi.org/10.15698/mic2016.04.491 |
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dig-cgspace-10568-729602023-10-02T12:52:59Z Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait Abt, Tom den Souffriau, Ben Foulquié Moreno, Maria R. Duitama, Jorge Thevelein, Johan genetic polymorphism genetic markers quantitative trait loci mutagenesis polimorfismo genético marcadores genéticos loci de rasgos cuantitativos molecular biology cell biology genetics microbiology parasitology virology Isolation of mutants in populations of microorganisms has been a valuable tool in experimental genetics for decades. The main disadvantage, however, is the inability of isolating mutants in non-selectable polygenic traits. Most traits of organisms, however, are non-selectable and polygenic, including industrially important properties of microorganisms. The advent of powerful technologies for polygenic analysis of complex traits has allowed simultaneous identification of multiple causative mutations among many thousands of irrelevant mutations. We now show that this also applies to haploid strains of which the genome has been loaded with induced mutations so as to affect as many non-selectable, polygenic traits as possible. We have introduced about 900 mutations into single haploid yeast strains using multiple rounds of EMS mutagenesis, while maintaining the mating capacity required for genetic mapping. We screened the strains for defects in flavor production, an important non-selectable, polygenic trait in yeast alcoholic beverage production. A haploid strain with multiple induced mutations showing reduced ethyl acetate production in semi-anaerobic fermentation, was selected and the underlying quantitative trait loci (QTLs) were mapped using pooled-segregant whole-genome sequence analysis after crossing with an unrelated haploid strain. Reciprocal hemizygosity analysis and allele exchange identified PMA1 and CEM1 as causative mutant alleles and TPS1 as a causative genetic background allele. The case of CEM1 revealed that relevant mutations without observable effect in the haploid strain with multiple induced mutations (in this case due to defective mitochondria) can be identified by polygenic analysis as long as the mutations have an effect in part of the segregants (in this case those that regained fully functional mitochondria). Our results show that genomic saturation mutagenesis combined with complex trait polygenic analysis could be used successfully to identify causative alleles underlying many non-selectable, polygenic traits in small collections of haploid strains with multiple induced mutations. 2016-04 2016-04-19T15:42:42Z 2016-04-19T15:42:42Z Journal Article Den Abt, Tom; Souffriau, Ben; Foulquié-Moreno, Maria R.; Duitama, Jorge; Thevelein, Johan M.. 2016. Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait . Microbial Cell 3(4): 159-175. 2311-2638 https://hdl.handle.net/10568/72960 https://doi.org/10.15698/mic2016.04.491 en Open Access p. 159-175 Shared Science Publishers OG Microbial Cell |
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genetic polymorphism genetic markers quantitative trait loci mutagenesis polimorfismo genético marcadores genéticos loci de rasgos cuantitativos molecular biology cell biology genetics microbiology parasitology virology genetic polymorphism genetic markers quantitative trait loci mutagenesis polimorfismo genético marcadores genéticos loci de rasgos cuantitativos molecular biology cell biology genetics microbiology parasitology virology |
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genetic polymorphism genetic markers quantitative trait loci mutagenesis polimorfismo genético marcadores genéticos loci de rasgos cuantitativos molecular biology cell biology genetics microbiology parasitology virology genetic polymorphism genetic markers quantitative trait loci mutagenesis polimorfismo genético marcadores genéticos loci de rasgos cuantitativos molecular biology cell biology genetics microbiology parasitology virology Abt, Tom den Souffriau, Ben Foulquié Moreno, Maria R. Duitama, Jorge Thevelein, Johan Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| description |
Isolation of mutants in populations of microorganisms has been a valuable tool in experimental genetics for decades. The main disadvantage, however, is the inability of isolating mutants in non-selectable polygenic traits. Most traits of organisms, however, are non-selectable and polygenic, including industrially important properties of microorganisms. The advent of powerful technologies for polygenic analysis of complex traits has allowed simultaneous identification of multiple causative mutations among many thousands of irrelevant mutations. We now show that this also applies to haploid strains of which the genome has been loaded with induced mutations so as to affect as many non-selectable, polygenic traits as possible. We have introduced about 900 mutations into single haploid yeast strains using multiple rounds of EMS mutagenesis, while maintaining the mating capacity required for genetic mapping. We screened the strains for defects in flavor production, an important non-selectable, polygenic trait in yeast alcoholic beverage production. A haploid strain with multiple induced mutations showing reduced ethyl acetate production in semi-anaerobic fermentation, was selected and the underlying quantitative trait loci (QTLs) were mapped using pooled-segregant whole-genome sequence analysis after crossing with an unrelated haploid strain. Reciprocal hemizygosity analysis and allele exchange identified PMA1 and CEM1 as causative mutant alleles and TPS1 as a causative genetic background allele. The case of CEM1 revealed that relevant mutations without observable effect in the haploid strain with multiple induced mutations (in this case due to defective mitochondria) can be identified by polygenic analysis as long as the mutations have an effect in part of the segregants (in this case those that regained fully functional mitochondria). Our results show that genomic saturation mutagenesis combined with complex trait polygenic analysis could be used successfully to identify causative alleles underlying many non-selectable, polygenic traits in small collections of haploid strains with multiple induced mutations. |
| format |
Journal Article |
| topic_facet |
genetic polymorphism genetic markers quantitative trait loci mutagenesis polimorfismo genético marcadores genéticos loci de rasgos cuantitativos molecular biology cell biology genetics microbiology parasitology virology |
| author |
Abt, Tom den Souffriau, Ben Foulquié Moreno, Maria R. Duitama, Jorge Thevelein, Johan |
| author_facet |
Abt, Tom den Souffriau, Ben Foulquié Moreno, Maria R. Duitama, Jorge Thevelein, Johan |
| author_sort |
Abt, Tom den |
| title |
Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| title_short |
Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| title_full |
Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| title_fullStr |
Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| title_full_unstemmed |
Genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| title_sort |
genomic saturation mutagenesis and polygenic analysis identify novel yeast genes affecting ethyl acetate production, a non-selectable polygenic trait |
| publisher |
Shared Science Publishers OG |
| publishDate |
2016-04 |
| url |
https://hdl.handle.net/10568/72960 https://doi.org/10.15698/mic2016.04.491 |
| work_keys_str_mv |
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| _version_ |
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