Manipulating yeast genome using plasmid vectors

Tim Stearns; Hong Ma; David Botstein

doi:10.1016/0076-6879(90)85025-J

Manipulating yeast genome using plasmid vectors

Tim Stearns, Hong Ma, David Botstein

Research output: Contribution to journal › Article › peer-review

68 Scopus citations

Abstract

The vectors and techniques described here enable one to manipulate the yeast genome to meet specific needs. Genes can be cloned, and the clone used to delete the wild-type gene from the chromosome, or replace it with mutant versions. Mutants derived by classical methods, such as mutagenesis of whole cells, or by reversion of a phenotype, can be cloned and analyzed in vitro. Yeast genes and foreign genes can either be inserted into autonomously replicating plasmid vectors that are reasonably stable or integrated into a yeast chromosome where they are maintained at one copy per genome. The combination of these techniques with the characterized promoter systems available in yeast make it possible to express almost any gene in yeast. Once this is achieved, the entire repertoire of yeast genetics is available to probe the function of the gene, or to engineer the expression in useful ways.

Original language	English (US)
Pages (from-to)	280-297
Number of pages	18
Journal	Methods in enzymology
Volume	185
Issue number	C
DOIs	https://doi.org/10.1016/0076-6879(90)85025-J
State	Published - Jan 1 1990

All Science Journal Classification (ASJC) codes

Biochemistry
Molecular Biology

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10.1016/0076-6879(90)85025-J

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AB - The vectors and techniques described here enable one to manipulate the yeast genome to meet specific needs. Genes can be cloned, and the clone used to delete the wild-type gene from the chromosome, or replace it with mutant versions. Mutants derived by classical methods, such as mutagenesis of whole cells, or by reversion of a phenotype, can be cloned and analyzed in vitro. Yeast genes and foreign genes can either be inserted into autonomously replicating plasmid vectors that are reasonably stable or integrated into a yeast chromosome where they are maintained at one copy per genome. The combination of these techniques with the characterized promoter systems available in yeast make it possible to express almost any gene in yeast. Once this is achieved, the entire repertoire of yeast genetics is available to probe the function of the gene, or to engineer the expression in useful ways.

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Manipulating yeast genome using plasmid vectors

Abstract

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