Combinatorial gene overexpression and recessive mutant gene introduction in sake yeast

Industrial yeast strains are generally diploid and are often defective in sporulation. Such strains are hence thought to be less tractable for manipulation by genetic engineering. To facilitate more reliable genetic manipulation of the diploid yeast Japanese sake, we constructed variants of this str...

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Bibliographic Details
Published in:Bioscience, biotechnology, and biochemistry biotechnology, and biochemistry, 2009, Vol.73 (3), p.633-640
Main Authors: Ano, A.(Iwata Chemical Co., Ltd., Shizuoka (Japan)), Suehiro, D, Cha-Aim, K, Aritomi, K, Phonimdaeng, P, Nontaso, N, Hoshida, H, Mizunuma, M, Miyakawa, T, Akada, R
Format: Article
Language:English
Subjects:
Biological and medical sciences
CLONACION
CLONAGE
CLONING
Diploidy
FERMENTACION
FERMENTATION
Fundamental and applied biological sciences. Psychology
Fungal Proteins - genetics
GENE
Gene Deletion
Gene Expression
gene targeting
Gene Transfer Techniques
GENES
Genes, Recessive - genetics
Genetic Markers - genetics
GENETIC TRANSFORMATION
GENETIC VARIATION
MUTANT
MUTANTES
MUTANTS
Mutation - genetics
PCR
S-adenosylmethionine
S-Adenosylmethionine - biosynthesis
SACCHAROMYCES CEREVISIAE
Saccharomyces cerevisiae - genetics
Saccharomyces cerevisiae - metabolism
sake yeast
SELECCION
SELECTION
self-cloning
TRANSFORMACION GENETICA
TRANSFORMATION GENETIQUE
VARIACION GENETICA
VARIATION GENETIQUE
VARIEDADES
VARIETE
VARIETIES
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Summary:Industrial yeast strains are generally diploid and are often defective in sporulation. Such strains are hence thought to be less tractable for manipulation by genetic engineering. To facilitate more reliable genetic manipulation of the diploid yeast Japanese sake, we constructed variants of this strain that were homozygous for a URA3 deletion, homozygous for either MAT a or MATα, and homozygous for either the his3 or the lys4 mutation. A ura3-null genotype enabled gene targeting to be undertaken more easily. The TDH3 promoter was inserted upstream of six yeast genes that have been implicated in flavor control to drive their constitutive overexpression. The homozygous MAT alleles, combined with the non-complementary auxotrophic mutations in the targeted transformants, allowed for tetraploid selection through mating. This resulted in the combinatorial construction of tetraploid strains that overexpress two different genes simultaneously. In addition, a recessive mutant gene, sah1-1, that is known to overproduce S-adenosylmethionine, was introduced into the diploid sake strain by the replacement of one wild-type allele and subsequent disruption of the other. The resulting sah1-1/sah1Δ::URA3 strain produced higher amounts of S-adenosylmethionine than the wild type. The novel sake yeast diploid strains we generated in this study can thus undergo simple PCR-mediated gene manipulation and mating in a manner analogous to established laboratory strains. Moreover, none of these sake strains had extraneous sequences, and they are thus suitable for use in commercial applications.
ISSN:0916-8451
1347-6947
DOI:10.1271/bbb.80708