Yeast transformation efficiency is enhanced by <scp>TORC</scp>1‐ and eisosome‐dependent signaling

Yu, Sheng-Chun; Kuemmel, Florian; Skoufou-Papoutsaki, Maria-Nefeli; Spanu, Pietro D.

doi:10.1002/mbo3.730

Cited by 5 publications

(5 citation statements)

References 46 publications

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“…However, this is of course merely speculation, and we have intentionally chosen not to attempt to decipher the exact molecular mechanism behind this effect in this work. Moreover, our results clearly support previous findings that Lithium acetate, DTT, ssDNA and elevated temperatures, are all factors of paramount importance for a successful yeast DNA transformation (2, 3, 5, 12). Although, we observe that these four parameters can, under some conditions, give rise to novel and unique transformation effects when applied in a nonconventional way, i.e., by using heat-shock and electroporation simultaneously.…”

Section: Discussionsupporting

confidence: 91%

“…Temperature (heat-shock) is also an important factor that stimulates extracellular DNA uptake during chemical transformation of yeast (2). However, unlike for bacteria, yeast chemical DNA transformation is currently understood to be mediated by endocytosis pathways (3), which is strongly enhanced by chemical agents, such as Lithium acetate, crowding agents (PEG) and nonspecific single-strand carrier DNA (ssDNA) (2, 3). In the case of bacterial and yeast DNA transformation mediated by electroporation, our current understanding suggests that a passive DNA diffusion through transiently formed pores in the membrane is the primary route of DNA uptake during electroporation (1, 4).…”

Section: Introductionmentioning

confidence: 99%

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Heat pre-treatment reduces multiplicity of plasmid transformations in yeast during electroporation, without diminishing the transformation efficiency

Wäneskog,

Hoch-Schneider,

Garg

et al. 2024

Preprint

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High-throughput DNA transformation techniques are invaluable when creating high-diversity mutant libraries, and the success rate of any protein engineering endeavors is directly dependent on both the size and diversity of the mutant library that is to be screened. It is also widely accepted that in both bacteria and yeast there is an inverse correlation between the DNA transformation efficiency and the likelihood of transforming multiple DNA molecules into each cell. However, most successful high-throughput mutant screening efforts require high quality libraries, i.e., libraries comprised of cells with a clear phenotype-to-genotype relationship (one genotype/cell). Thus, DNA transformation methods with a high multiplicity of transformation are highly undesirable and detrimental to most mutant screening assays. Here we describe a simple, robust, and highly efficient yeast plasmid DNA transformation methodology, using a dual heat-shock and electroporation approach (HEEL) that generates more than 2 x 107plasmid-transformed yeast cells per reaction, while simultaneously increasing the fraction of mono-transformed cells from 20% to more than 70% of the transformed population. By also using an automated yeast genotyping workflow coupled with a dual-barcoding approach, consisting of a SNP and high-diversity barcode (10N), we can consistently identify and enumerate unique plasmid genotypes within a heterogeneous population merely through Sanger sequencing. We demonstrate here that the size and quality of a transformed library no longer need to be inversely correlated when transforming large mutant DNA libraries in yeast using highly efficient DNA electroporation methods.SignificanceWith the recent expansion of artificial intelligence in the field of synthetic biology there has never been a greater need for high-quality data and reliable measurements of phenotype-to-genotype relationships. However, one major obstacle to creating accurate computer-based models is the current abundance of low-quality phenotypic measurements originating from numerous high-throughput, but low-resolution assays. Rather than increasing the quantity of measurements, new studies should aim to generate as accurate measurements as possible. The HEEL methodology presented here aims to address this issue by minimizing the problem of multi-plasmid uptake during high-throughput yeast DNA transformations, which leads to the creation of heterogeneous cellular genotypes. HEEL should enable highly accurate phenotype-to-genotype measurements going forward, which could be used to construct better computer-based models.

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Heat pre-treatment reduces multiplicity of plasmid transformations in yeast during electroporation, without diminishing the transformation efficiency

Wäneskog,

Hoch-Schneider,

Garg

et al. 2024

Preprint

View full text Add to dashboard Cite

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“…While intensive efforts have been made to turn E. coli into a universal molecular biology tool, the power of S. cerevisiae as DNA assembly platform has so far been largely untapped. Despite the pivotal role played by S. cerevisiae in the last decade in the assembly of genomes ( 14 , 55–58 ) there is so far relatively little effort invested in turning this yeast into a universal and powerful DNA assembly platform ( 59 , 60 ), a situation that we expect will change in the future.…”

Section: Discussionmentioning

confidence: 99%

A supernumerary designer chromosome for modular in vivo pathway assembly in Saccharomyces cerevisiae

Postma

Dashko

Breemen

et al. 2021

Nucleic Acids Research

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The construction of microbial cell factories for sustainable production of chemicals and pharmaceuticals requires extensive genome engineering. Using Saccharomyces cerevisiae, this study proposes synthetic neochromosomes as orthogonal expression platforms for rewiring native cellular processes and implementing new functionalities. Capitalizing the powerful homologous recombination capability of S. cerevisiae, modular neochromosomes of 50 and 100 kb were fully assembled de novo from up to 44 transcriptional-unit-sized fragments in a single transformation. These assemblies were remarkably efficient and faithful to their in silico design. Neochromosomes made of non-coding DNA were stably replicated and segregated irrespective of their size without affecting the physiology of their host. These non-coding neochromosomes were successfully used as landing pad and as exclusive expression platform for the essential glycolytic pathway. This work pushes the limit of DNA assembly in S. cerevisiae and paves the way for de novo designer chromosomes as modular genome engineering platforms in S. cerevisiae.

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“…The more targets to be edited, the more donor DNA and/or gRNA cassettes will be required. Transformation techniques, such as electroporation or the addition of amino acids, can be incorporated to improve the transformation efficiency ( Benatuil et al, 2010 ; Yu et al, 2019 ). Finally, the development of CRISPR/Cas9 multiplex genome integration in yeast can be improved by combining multiple methods.…”

Section: Perspectivesmentioning

confidence: 99%

Multiplex Genome Editing in Yeast by CRISPR/Cas9 – A Potent and Agile Tool to Reconstruct Complex Metabolic Pathways

Utomo

Hodgins

2021

Front. Plant Sci.

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Numerous important pharmaceuticals and nutraceuticals originate from plant specialized metabolites, most of which are synthesized via complex biosynthetic pathways. The elucidation of these pathways is critical for the applicable uses of these compounds. Although the rapid progress of the omics technology has revolutionized the identification of candidate genes involved in these pathways, the functional characterization of these genes remains a major bottleneck. Baker’s yeast (Saccharomyces cerevisiae) has been used as a microbial platform for characterizing newly discovered metabolic genes in plant specialized metabolism. Using yeast for the investigation of numerous plant enzymes is a streamlined process because of yeast’s efficient transformation, limited endogenous specialized metabolism, partially sharing its primary metabolism with plants, and its capability of post-translational modification. Despite these advantages, reconstructing complex plant biosynthetic pathways in yeast can be time intensive. Since its discovery, CRISPR/Cas9 has greatly stimulated metabolic engineering in yeast. Yeast is a popular system for genome editing due to its efficient homology-directed repair mechanism, which allows precise integration of heterologous genes into its genome. One practical use of CRISPR/Cas9 in yeast is multiplex genome editing aimed at reconstructing complex metabolic pathways. This system has the capability of integrating multiple genes of interest in a single transformation, simplifying the reconstruction of complex pathways. As plant specialized metabolites usually have complex multigene biosynthetic pathways, the multiplex CRISPR/Cas9 system in yeast is suited well for functional genomics research in plant specialized metabolism. Here, we review the most advanced methods to achieve efficient multiplex CRISPR/Cas9 editing in yeast. We will also discuss how this powerful tool has been applied to benefit the study of plant specialized metabolism.

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Yeast transformation efficiency is enhanced by TORC1‐ and eisosome‐dependent signaling

Cited by 5 publications

References 46 publications

Heat pre-treatment reduces multiplicity of plasmid transformations in yeast during electroporation, without diminishing the transformation efficiency

Heat pre-treatment reduces multiplicity of plasmid transformations in yeast during electroporation, without diminishing the transformation efficiency

A supernumerary designer chromosome for modular in vivo pathway assembly in Saccharomyces cerevisiae

Multiplex Genome Editing in Yeast by CRISPR/Cas9 – A Potent and Agile Tool to Reconstruct Complex Metabolic Pathways

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