Knocking out multigene redundancies via cycles of sexual assortment and fluorescence selection

Suzuki, Yo; St.Onge, Robert P.; Mani, Ramamurthy; King, Oliver D.; Heilbut, Adrian; Labunskyy, Vyacheslav M.; Chen, Weidong; Pham, Linda; Zhang, Lan V.; Tong, Amy; Nislow, Corey; Giaever, Guri; Gladyshev, Vadim N.; Vidal, Marc; Schow, Peter; Lehár, Joseph; Roth, Frederick P.

doi:10.1038/nmeth.1550

Cited by 74 publications

(116 citation statements)

References 36 publications

(44 reference statements)

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“…Poor cell permeability can be an obstacle of cellbased assays in yeast, whose cell wall and elaborate chemical defense mechanisms represent a formidable barrier to many chemical compounds. Although it is unclear how many compounds were actually able to penetrate into yeast, prescreening compounds for growth inhibition of a wild-type strain, applying computational models to prioritize cell-permeable bioactive compounds (34), or genetically disabling yeast's chemical defense mechanisms (35,36) could each increase the number of compounds effectively entering the cell in future studies. Indeed, in the current study our "hit rate" was much higher for growth inhibitory compounds, as 13 of the 14 growth inhibitors identified at least one change in our multiplex assay.…”

Section: Discussionmentioning

confidence: 99%

“…The utility of yeast as a model for studying multidrug resistance is supported by its vast repertoire of drug transporters (29,35) and by the homology of both Pdr5 and Snq2 to human Mdr1, a major contributor to tumor resistance (43,44). Of the 80 chemicals screened in this study, 21 (26.25%) yielded an interaction score >10 in at least one of three drug-pump strains (Pdr5:Pdr5, Snq2:Snq2, or Tpo1: Pdr5).…”

Section: Discussionmentioning

confidence: 99%

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Multiplex assay for condition-dependent changes in protein–protein interactions

Schlecht

Miranda

Suresh

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Changes in protein-protein interactions that occur in response to environmental cues are difficult to uncover and have been poorly characterized to date. Here we describe a yeast-based assay that allows many binary protein interactions to be assessed in parallel and under various conditions. This method combines molecular barcoding and tag array technology with the murine dihydrofolate reductase-based protein-fragment complementation assay. A total of 238 protein-fragment complementation assay strains, each representing a unique binary protein complex, were tagged with molecular barcodes, pooled, and then interrogated against a panel of 80 diverse small molecules. Our method successfully identified specific disruption of the Hom3:Fpr1 interaction by the immunosuppressant FK506, illustrating the assay's capacity to identify chemical inhibitors of protein-protein interactions. Among the additional findings was specific cellular depletion of the Dst1:Rbp9 complex by the anthracycline drug doxorubicin, but not by the related drug idarubicin. The assay also revealed chemical-induced accumulation of several binary multidrug transporter complexes that largely paralleled increases in transcript levels. Further assessment of two such interactions (Tpo1: Pdr5 and Snq2:Pdr5) in the presence of 1,246 unique chemical compounds revealed a positive correlation between drug lipophilicity and the drug response in yeast.protein network | cell-based assay | drug screening | chemogenomics P rotein-protein interactions (PPIs) are of fundamental importance to virtually all cellular processes, including signal transduction and regulation of gene expression. Emergent highthroughput technologies that identify protein complexes and/or binary interactions have produced a wealth of information and have further underscored the ubiquitous role that PPIs play in cell biology (1-8). Although changes in protein complexes can occur from routine biochemical signaling events (i.e., posttranslational modification, protein degradation, or relocalization), the aforementioned studies were performed under standard growth conditions, and thus network connectivity changes that occur in response to different environmental cues remain ill-defined. Measuring such changes-for example, in response to chemical (i.e., small molecule) perturbations-is valuable in understanding both cellular systems and the biological effects of the chemical in question (9).The cell's "interactome" also represents a tremendous opportunity for unique therapeutic strategies. Small-molecule drugs that directly inhibit specific PPIs could be used to modulate the activity of certain cellular processes while minimally interfering with others. PPIs are perceived to be among the most challenging targets for small molecules because of the sheer size of the interaction interface and the lack of small, deep cavities amenable to small-molecule binding (reviewed in ref. 10). Thus, despite an ever-increasing commitment by drug developers to pursue PPIs, and a growing list of small molecules th...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Multiplex assay for condition-dependent changes in protein–protein interactions

Schlecht

Miranda

Suresh

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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“…To meet the first of these needs, altering the genetic background, classic mutagenesis techniques such as mutator strains can be useful for phenotypic optimization, but they do not provide control over the extent and location of mutations (49), unlike several notable, recently reported techniques. Exploiting sexual reproduction in S. cerevisiae, Suzuki et al have used iterative cycles of mating and sporulation along with a quantitative GFP marker to gather up to 16 deletion mutations in an individual strain (50). Using an E. coli strain engineered with the λ Red recombination system (36), multiplex automated genome engineering automates the transformation of mutagenic singlestranded oligonucleotides ∼90 bases in length to create a powerful method for introducing specified deletions, point mutations, and very short insertions of ≤30 base pairs anywhere in the chromosome, but it has not been shown to be capable of efficient whole-gene insertion in its current form (see Note.)…”

Section: Discussionmentioning

confidence: 99%

Reiterative Recombination for the in vivo assembly of libraries of multigene pathways

Wingler

Cornish

2011

Proc. Natl. Acad. Sci. U.S.A.

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The increasing sophistication of synthetic biology is creating a demand for robust, broadly accessible methodology for constructing multigene pathways inside of the cell. Due to the difficulty of rationally designing pathways that function as desired in vivo, there is a further need to assemble libraries of pathways in parallel, in order to facilitate the combinatorial optimization of performance. While some in vitro DNA assembly methods can theoretically make libraries of pathways, these techniques are resource intensive and inherently require additional techniques to move the DNA back into cells. All previously reported in vivo assembly techniques have been low yielding, generating only tens to hundreds of constructs at a time. Here, we develop “Reiterative Recombination,” a robust method for building multigene pathways directly in the yeast chromosome. Due to its use of endonuclease-induced homologous recombination in conjunction with recyclable markers, Reiterative Recombination provides a highly efficient, technically simple strategy for sequentially assembling an indefinite number of DNA constructs at a defined locus. In this work, we describe the design and construction of the first Reiterative Recombination system in Saccharomyces cerevisiae , and we show that it can be used to assemble multigene constructs. We further demonstrate that Reiterative Recombination can construct large mock libraries of at least 10 4 biosynthetic pathways. We anticipate that our system’s simplicity and high efficiency will make it a broadly accessible technology for pathway construction and render it a valuable tool for optimizing pathways in vivo.

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“…Because the number of markers is limited, methods have been developed for removing and reusing the same marker 5,6,7,8,9,10 . However, sequentially engineering multiple mutations using these methods is time-consuming because the time required scales linearly with the number of deletions to be generated.Here we describe the Green Monster method for routinely engineering multiple deletions in yeast 11 . In this method, a green fluorescent protein (GFP) reporter integrated into deletions is used to quantitatively label strains according to the number of deletions contained in each strain (Figure 1).…”

mentioning

confidence: 99%

“…Here we describe the Green Monster method for routinely engineering multiple deletions in yeast 11 . In this method, a green fluorescent protein (GFP) reporter integrated into deletions is used to quantitatively label strains according to the number of deletions contained in each strain (Figure 1).…”

mentioning

confidence: 99%

The Green Monster Process for the Generation of Yeast Strains Carrying Multiple Gene Deletions

Suzuki

Stam

Novotny

et al. 2012

JoVE

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Phenotypes for a gene deletion are often revealed only when the mutation is tested in a particular genetic background or environmental condition 1,2 . There are examples where many genes need to be deleted to unmask hidden gene functions 3,4 . Despite the potential for important discoveries, genetic interactions involving three or more genes are largely unexplored. Exhaustive searches of multi-mutant interactions would be impractical due to the sheer number of possible combinations of deletions. However, studies of selected sets of genes, such as sets of paralogs with a greater a priori chance of sharing a common function, would be informative.In the yeast Saccharomyces cerevisiae, gene knockout is accomplished by replacing a gene with a selectable marker via homologous recombination. Because the number of markers is limited, methods have been developed for removing and reusing the same marker 5,6,7,8,9,10 . However, sequentially engineering multiple mutations using these methods is time-consuming because the time required scales linearly with the number of deletions to be generated.Here we describe the Green Monster method for routinely engineering multiple deletions in yeast 11 . In this method, a green fluorescent protein (GFP) reporter integrated into deletions is used to quantitatively label strains according to the number of deletions contained in each strain (Figure 1). Repeated rounds of assortment of GFP-marked deletions via yeast mating and meiosis coupled with flow-cytometric enrichment of strains carrying more of these deletions lead to the accumulation of deletions in strains (Figure 2). Performing multiple processes in parallel, with each process incorporating one or more deletions per round, reduces the time required for strain construction.The first step is to prepare haploid single-mutants termed 'ProMonsters,' each of which carries a GFP reporter in a deleted locus and one of the 'toolkit' loci-either Green Monster GMToolkit-a or GMToolkit-α at the can1Δ locus (Figure 3). Using strains from the yeast deletion collection 12 , GFP-marked deletions can be conveniently generated by replacing the common KanMX4 cassette existing in these strains with a universal GFP-URA3 fragment. Each GMToolkit contains: either the a-or α-mating-type-specific haploid selection marker 1 and exactly one of the two markers that, when both GMToolkits are present, collectively allow for selection of diploids.The second step is to carry out the sexual cycling through which deletion loci can be combined within a single cell by the random assortment and/or meiotic recombination that accompanies each cycle of mating and sporulation. Video LinkThe video component of this article can be found at http://www.jove.com/video/4072/ Protocol 1. Generation of ProMonsters 1. Prepare the universal GFP replacement cassette by amplifying a tetO 2 -GFP marker and the URA3 marker from the plasmid pYOGM012 (ampicillin resistance) using primers with sequences:GGATCCCCGGGTTAATTAAGGCGCGCCAGATCTGTTTAGCTTGCCCAAGCTCCTCGAGTAATTCG and GGCGT...

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Knocking out multigene redundancies via cycles of sexual assortment and fluorescence selection

Cited by 74 publications

References 36 publications

Multiplex assay for condition-dependent changes in protein–protein interactions

Multiplex assay for condition-dependent changes in protein–protein interactions

Reiterative Recombination for the in vivo assembly of libraries of multigene pathways

The Green Monster Process for the Generation of Yeast Strains Carrying Multiple Gene Deletions

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