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Literature DB >> 25209147

High-efficiency genome editing and allele replacement in prototrophic and wild strains of Saccharomyces.

William G Alexander¹, Drew T Doering², Chris Todd Hittinger³.

Abstract

Current genome editing techniques available for Saccharomyces yeast species rely on auxotrophic markers, limiting their use in wild and industrial strains and species. Taking advantage of the ancient loss of thymidine kinase in the fungal kingdom, we have developed the herpes simplex virus thymidine kinase gene as a selectable and counterselectable marker that forms the core of novel genome engineering tools called the H: aploid E: ngineering and R: eplacement P: rotocol (HERP) cassettes. Here we show that these cassettes allow a researcher to rapidly generate heterogeneous populations of cells with thousands of independent chromosomal allele replacements using mixed PCR products. We further show that the high efficiency of this approach enables the simultaneous replacement of both alleles in diploid cells. Using these new techniques, many of the most powerful yeast genetic manipulation strategies are now available in wild, industrial, and other prototrophic strains from across the diverse Saccharomyces genus.

Entities: Species

Keywords: Saccharomyces; genome editing; prototroph; synthetic biology; thymidine kinase

Mesh：

Substances：

Year: 2014 PMID： 25209147 PMCID： PMC4224175 DOI： 10.1534/genetics.114.170118

Source DB: PubMed Journal: Genetics ISSN： 0016-6731 Impact factor: 4.562

54 in total

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Authors: Rachel E Haurwitz; Martin Jinek; Blake Wiedenheft; Kaihong Zhou; Jennifer A Doudna
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Authors: Michael Mülleder; Floriana Capuano; Pınar Pir; Stefan Christen; Uwe Sauer; Stephen G Oliver; Markus Ralser
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14 in total

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10. Genome-wide association across Saccharomyces cerevisiae strains reveals substantial variation in underlying gene requirements for toxin tolerance.

Authors: Maria Sardi; Vaishnavi Paithane; Michael Place; De Elegant Robinson; James Hose; Dana J Wohlbach; Audrey P Gasch
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