Superloser: a plasmid shuffling vector for Saccharomyces cerevisiae with exceedingly low background

Mapping Intimacies ◽

10.1101/630863 ◽

2019 ◽

Author(s):

Max A. B. Haase ◽

David M. Truong ◽

Jef D. Boeke

Keyword(s):

Saccharomyces Cerevisiae ◽

Sequence Similarity ◽

Acid Resistance ◽

Petri Dish ◽

Proof Of Concept ◽

Yeast Gene ◽

Low Background ◽

Plasmid Segregation ◽

Core Histones ◽

Yeast Plasmids

AbstractHere we report a new plasmid shuffle vector for forcing budding yeast (Saccharomyces cerevisiae) to incorporate a new genetic pathway in place of a native pathway – even essential ones – while maintaining low false positive rates (less than 1 in 108 per cell). This plasmid, dubbed “Superloser”, was designed with reduced sequence similarity to commonly used yeast plasmids (i.e. pRS400 series) to limit recombination, a process that in our experience leads to retention of the yeast gene(s) instead of the desired gene(s). In addition, Superloser utilizes two orthogonal copies of the counter-selectable marker URA3 to reduce spontaneous 5-fluoroorotic acid resistance. Finally, the CEN/ARS sequence is fused to the GAL1-10 promoter, which disrupts plasmid segregation in the presence of the sugar galactose, causing Superloser to rapidly be removed from a population of cells. We show one proof of concept shuffling experiment: swapping yeast’s core histones out for their human counterparts. Superloser is especially useful for forcing yeast to use highly unfavorable genes, such as human histones, as it enables plating a large number of cells (1.4×109) on a single 10 cm petri dish while maintaining a very low background. Therefore, Superloser is a useful tool for yeast geneticists to effectively shuffle low viability genes and/or pathways in yeast that may arise in as low as 1 in 108 cells.

Expression of an ATP-binding cassette transporter-encoding gene (YOR1) is required for oligomycin resistance in Saccharomyces cerevisiae.

Molecular and Cellular Biology ◽

10.1128/mcb.15.12.6875 ◽

1995 ◽

Vol 15 (12) ◽

pp. 6875-6883 ◽

Cited By ~ 165

Author(s):

D J Katzmann ◽

T C Hallstrom ◽

M Voet ◽

W Wysock ◽

J Golin ◽

...

Keyword(s):

Saccharomyces Cerevisiae ◽

Fusion Gene ◽

Sequence Similarity ◽

Yeast Cells ◽

Atp Binding ◽

Zinc Cluster ◽

Atp Binding Cassette Transporter ◽

Transporter Family ◽

Encoding Gene ◽

Atp Binding Cassette

Semidominant mutations in the PDR1 or PDR3 gene lead to elevated resistance to cycloheximide and oligomycin. PDR1 and PDR3 have been demonstrated to encode zinc cluster transcription factors. Cycloheximide resistance mediated by PDR1 and PDR3 requires the presence of the PDR5 membrane transporter-encoding gene. However, PDR5 is not required for oligomycin resistance. Here, we isolated a gene that is necessary for PDR1- and PDR3-mediated oligomycin resistance. This locus, designated YOR1, causes a dramatic elevation in oligomycin resistance when present in multiple copies. A yor1 strain exhibits oligomycin hypersensitivity relative to an isogenic wild-type strain. In addition, loss of the YOR1 gene blocks the elevation in oligomycin resistance normally conferred by mutant forms of PDR1 or PDR3. The YOR1 gene product is predicted to be a member of the ATP-binding cassette transporter family of membrane proteins. Computer alignment indicates that Yor1p shows striking sequence similarity with multidrug resistance-associated protein, Saccharomyces cerevisiae Ycf1p, and the cystic fibrosis transmembrane conductance regulator. Use of a YOR1-lacZ fusion gene indicates that YOR1 expression is responsive to PDR1 and PDR3. While PDR5 expression is strictly dependent on the presence of PDR1 or PDR3, control of YOR1 expression has a significant PDR1/PDR3-independent component. Taken together, these data indicate that YOR1 provides the link between transcriptional regulation by PDR1 and PDR3 and oligomycin resistance of yeast cells.

Histone H1 expressed in Saccharomyces cerevisiae binds to chromatin and affects survival, growth, transcription, and plasmid stability but does not change nucleosomal spacing

Molecular and Cellular Biology ◽

10.1128/mcb.14.4.2822-2835.1994 ◽

1994 ◽

Vol 14 (4) ◽

pp. 2822-2835

Author(s):

C Linder ◽

F Thoma

Keyword(s):

Saccharomyces Cerevisiae ◽

Plasmid Stability ◽

Apparent Molecular Weight ◽

Histone H1 ◽

Expression Levels ◽

Inhibition Of Growth ◽

Gene Coding ◽

Gal1 Promoter ◽

Core Histones ◽

Low Levels

Histone H1 is proposed to serve a structural role in nucleosomes and chromatin fibers, to affect the spacing of nucleosomes, and to act as a general repressor of transcription. To test these hypotheses, a gene coding for a sea urchin histone H1 was expressed from the inducible GAL1 promoter in Saccharomyces cerevisiae by use of a YEp vector for high expression levels (strain YCL7) and a centromere vector for low expression levels (strain YCL1). The H1 protein was identified by its inducibility in galactose, its apparent molecular weight, and its solubility in 5% perchloric acid. When YCL7 was shifted from glucose to galactose for more than 40 h to achieve maximal levels of H1, H1 could be copurified in approximately stoichiometric amounts with core histones of Nonidet P-40-washed nuclei and with soluble chromatin fractionated on sucrose gradients. While S. cerevisiae tolerated the expression of low levels of H1 in YCL1 without an obvious phenotype, the expression of high levels of H1 correlated with greatly reduced survival, inhibition of growth, and increased plasmid loss but no obvious change in the nucleosomal repeat length. After an initial induction, RNA levels for GAL1 and H1 were drastically reduced, suggesting that H1 acts by the repression of galactose-induced genes. Similar effects, but to a lower extent, were observed when the C-terminal tail of H1 was expressed.

Yeast repressor alpha 2 binds to its operator cooperatively with yeast protein Mcm1.

Molecular and Cellular Biology ◽

10.1128/mcb.9.11.5228 ◽

1989 ◽

Vol 9 (11) ◽

pp. 5228-5230 ◽

Cited By ~ 54

Author(s):

C A Keleher ◽

S Passmore ◽

A D Johnson

Keyword(s):

Saccharomyces Cerevisiae ◽

Gene Product ◽

Strong Evidence ◽

Regulatory Proteins ◽

Yeast Cells ◽

Specific Gene ◽

Yeast Gene ◽

Yeast Protein ◽

Transcriptional Regulatory

To bring about repression of a family fo genes in Saccharomyces cerevisiae called the a-specific genes, two transcriptional regulatory proteins, alpha 2 and GRM (general regulator of matin type), bind cooperatively to an operator found upstream of each a-specific gene. To date, GRM has been defined only biochemically. In this communication we show that the product of a single yeast gene (MCM1) is sufficient to bind cooperatively with alpha 2 to the operator. We also show that antiserum raised against the MCM1 gene product recognizes GRM from yeast cells. These results, in combination with previous observations, provide strong evidence that MCM1 encodes the GRM activity.

Bidirectional titration of yeast gene expression using a pooled CRISPR guide RNA approach

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2007413117 ◽

2020 ◽

Vol 117 (31) ◽

pp. 18424-18430 ◽

Cited By ~ 2

Author(s):

Emily K. Bowman ◽

Matthew Deaner ◽

Jan-Fang Cheng ◽

Robert Evans ◽

Ernst Oberortner ◽

...

Keyword(s):

Gene Expression ◽

Saccharomyces Cerevisiae ◽

Essential Genes ◽

Yeast Gene ◽

Promoter Regions ◽

Guide Rna ◽

Metabolic Genes ◽

Complementary Approach ◽

Modulation Of Gene Expression ◽

Generation Sequencing

Most classic genetic approaches utilize binary modifications that preclude the identification of key knockdowns for essential genes or other targets that only require moderate modulation. As a complementary approach to these classic genetic methods, we describe a plasmid-based library methodology that affords bidirectional, graded modulation of gene expression enabled by tiling the promoter regions of all 969 genes that comprise the ito977 model ofSaccharomyces cerevisiae’s metabolic network. When coupled with a CRISPR-dCas9–based modulation and next-generation sequencing, this method affords a library-based, bidirection titration of gene expression across all major metabolic genes. We utilized this approach in two case studies: growth enrichment on alternative sugars, glycerol and galactose, and chemical overproduction of betaxanthins, leading to the identification of unique gene targets. In particular, we identify essential genes and other targets that were missed by classic genetic approaches.

Yeast Plasmids: The 2-μm Cricle Plasmid of Saccharomyces Cerevisiae

Molecular Biology and Genetic Engineering of Yeasts ◽

10.1201/9781351074735-2 ◽

2018 ◽

pp. 41-55

Author(s):

Henri Heslot ◽

Claude Gaillardin

Keyword(s):

Saccharomyces Cerevisiae ◽

Yeast Plasmids

Isolation and characterization of PEP3, a gene required for vacuolar biogenesis in Saccharomyces cerevisiae

Molecular and Cellular Biology ◽

10.1128/mcb.11.12.5801-5812.1991 ◽

1991 ◽

Vol 11 (12) ◽

pp. 5801-5812

Author(s):

R A Preston ◽

M F Manolson ◽

K Becherer ◽

E Weidenhammer ◽

D Kirkpatrick ◽

...

Keyword(s):

Saccharomyces Cerevisiae ◽

Gene Product ◽

Zinc Finger ◽

Genomic Library ◽

Sequence Similarity ◽

Carboxypeptidase Y ◽

Lag Phase ◽

Significant Similarity ◽

Reading Frame ◽

Isolation And Characterization

The Saccharomyces cerevisiae PEP3 gene was cloned from a wild-type genomic library by complementation of the carboxypeptidase Y deficiency in a pep3-12 strain. Subclone complementation results localized the PEP3 gene to a 3.8-kb DNA fragment. The DNA sequence of the fragment was determined; a 2,754-bp open reading frame predicts that the PEP3 gene product is a hydrophilic, 107-kDa protein that has no significant similarity to any known protein. The PEP3 predicted protein has a zinc finger (CX2CX13CX2C) near its C terminus that has spacing and slight sequence similarity to the adenovirus E1a zinc finger. A radiolabeled PEP3 DNA probe hybridized to an RNA transcript of 3.1 kb in extracts of log-phase and diauxic lag-phase cells. Cells bearing pep3 deletion/disruption alleles were viable, had decreased levels of protease A, protease B, and carboxypeptidase Y antigens, had decreased repressible alkaline phosphatase activity, and contained very few normal vacuolelike organelles by fluorescence microscopy and electron microscopy but had an abundance of extremely small vesicles that stained with carboxyfluorescein diacetate, were severely inhibited for growth at 37 degrees C, and were incapable of sporulating (as homozygotes). Fractionation of cells expressing a bifunctional PEP3::SUC2 fusion protein indicated that the PEP3 gene product is present at low abundance in both log-phase and stationary cells and is a vacuolar peripheral membrane protein. Sequence identity established that PEP3 and VPS18 (J. S. Robinson, T. R. Graham, and S. D. Emr, Mol. Cell. Biol. 11:5813-5824, 1991) are the same gene.

RPC82 encodes the highly conserved, third-largest subunit of RNA polymerase C (III) from Saccharomyces cerevisiae.

Molecular and Cellular Biology ◽

10.1128/mcb.12.10.4433 ◽

1992 ◽

Vol 12 (10) ◽

pp. 4433-4440 ◽

Cited By ~ 13

Author(s):

N Chiannilkulchai ◽

R Stalder ◽

M Riva ◽

C Carles ◽

M Werner ◽

...

Keyword(s):

Saccharomyces Cerevisiae ◽

Rna Polymerase ◽

Stop Codon ◽

Sequence Similarity ◽

Start Codon ◽

Rrna Synthesis ◽

Temperature Sensitive ◽

In Vitro Mutagenesis ◽

Multicopy Plasmid

RNA polymerase C (III) promotes the transcription of tRNA and 5S RNA genes. In Saccharomyces cerevisiae, the enzyme is composed of 15 subunits, ranging from 160 to about 10 kDa. Here we report the cloning of the gene encoding the 82-kDa subunit, RPC82. It maps as a single-copy gene on chromosome XVI. The UCR2 gene was found in the opposite orientation only 340 bp upstream of the RPC82 start codon, and the end of the SKI3 coding sequence was found only 117 bp downstream of the RPC82 stop codon. The RPC82 gene encodes a protein with a predicted M(r) of 73,984, having no strong sequence similarity to other known proteins. Disruption of the RPC82 gene was lethal. An rpc82 temperature-sensitive mutant, constructed by in vitro mutagenesis of the gene, showed a deficient rate of tRNA relative to rRNA synthesis. Of eight RNA polymerase C genes tested, only the RPC31 gene on a multicopy plasmid was capable of suppressing the rpc82(Ts) defect, suggesting an interaction between the polymerase C 82-kDa and 31-kDa subunits. A group of RNA polymerase C-specific subunits are proposed to form a substructure of the enzyme.

Automatic Identification of Players in the Flavonoid Biosynthesis with Application on the Biomedicinal Plant Croton tiglium

Plants ◽

10.3390/plants9091103 ◽

2020 ◽

Vol 9 (9) ◽

pp. 1103

Author(s):

Boas Pucker ◽

Franziska Reiher ◽

Hanna Marie Schilbert

Keyword(s):

Sequence Similarity ◽

Transcriptome Assembly ◽

Flavonoid Biosynthesis ◽

Automatic Identification ◽

Amino Acid Residues ◽

Proof Of Concept ◽

Pollinator Attraction ◽

Biotechnological Potential ◽

Knowledge Based ◽

Croton Tiglium

The flavonoid biosynthesis is a well-characterised model system for specialised metabolism and transcriptional regulation in plants. Flavonoids have numerous biological functions such as UV protection and pollinator attraction, but also biotechnological potential. Here, we present Knowledge-based Identification of Pathway Enzymes (KIPEs) as an automatic approach for the identification of players in the flavonoid biosynthesis. KIPEs combines comprehensive sequence similarity analyses with the inspection of functionally relevant amino acid residues and domains in subjected peptide sequences. Comprehensive sequence sets of flavonoid biosynthesis enzymes and knowledge about functionally relevant amino acids were collected. As a proof of concept, KIPEs was applied to investigate the flavonoid biosynthesis of the medicinal plant Croton tiglium on the basis of a transcriptome assembly. Enzyme candidates for all steps in the biosynthesis network were identified and matched to previous reports of corresponding metabolites in Croton species.

Cloning and characterization of FAD1, the structural gene for flavin adenine dinucleotide synthetase of Saccharomyces cerevisiae.

Molecular and Cellular Biology ◽

10.1128/mcb.15.1.264 ◽

1995 ◽

Vol 15 (1) ◽

pp. 264-271 ◽

Cited By ~ 63

Author(s):

M Wu ◽

B Repetto ◽

D M Glerum ◽

A Tzagoloff

Keyword(s):

Saccharomyces Cerevisiae ◽

Flavin Adenine Dinucleotide ◽

Genomic Library ◽

Sequence Similarity ◽

Complementation Group ◽

Flavin Mononucleotide ◽

Synthetase Activity ◽

Multicopy Plasmid ◽

Multiple Copies ◽

Extragenic Suppression

The FAD1 gene of Saccharomyces cerevisiae has been selected from a genomic library on the basis of its ability to partially correct the respiratory defect of pet mutants previously assigned to complementation group G178. Mutants in this group display a reduced level of flavin adenine dinucleotide (FAD) and an increased level of flavin mononucleotide (FMN) in mitochondria. The restoration of respiratory capability by FAD1 is shown to be due to extragenic suppression. FAD1 codes for an essential yeast protein, since disruption of the gene induces a lethal phenotype. The FAD1 product has been inferred to be yeast FAD synthetase, an enzyme that adenylates FMN to FAD. This conclusion is based on the following evidence. S. cerevisiae transformed with FAD1 on a multicopy plasmid displays an increase in FAD synthetase activity. This is also true when the gene is expressed in Escherichia coli. Lastly, the FAD1 product exhibits low but significant primary sequence similarity to sulfate adenyltransferase, which catalyzes a transfer reaction analogous to that of FAD synthetase. The lower mitochondrial concentration of FAD in G178 mutants is proposed to be caused by an inefficient exchange of external FAD for internal FMN. This is supported by the absence of FAD synthetase activity in yeast mitochondria and the presence of both extramitochondrial and mitochondrial riboflavin kinase, the preceding enzyme in the biosynthetic pathway. A lesion in mitochondrial import of FAD would account for the higher concentration of mitochondrial FMN in the mutant if the transport is catalyzed by an exchange carrier. The ability of FAD1 to suppress impaired transport of FAD is explained by mislocalization of the synthetase in cells harboring multiple copies of the gene. This mechanism of suppression is supported by the presence of mitochondrial FAD synthetase activity in S. cerevisiae transformed with FAD1 on a high-copy-number plasmid but not in mitochondrial of a wild-type strain.

A Nuclear Import Pathway for a Protein Involved in tRNA Maturation

The Journal of Cell Biology ◽

10.1083/jcb.139.7.1655 ◽

1997 ◽

Vol 139 (7) ◽

pp. 1655-1661 ◽

Cited By ~ 68

Author(s):

Jonathan S. Rosenblum ◽

Lucy F. Pemberton ◽

Günter Blobel

Keyword(s):

Saccharomyces Cerevisiae ◽

Nuclear Import ◽

Ribosomal Proteins ◽

Ribosome Biogenesis ◽

Sequence Similarity ◽

Wild Type ◽

Major Pathway ◽

Trna Processing ◽

Transport Factors ◽

Limited Sequence

A limited number of transport factors, or karyopherins, ferry particular substrates between the cytoplasm and nucleoplasm. We identified the Saccharomyces cerevisiae gene YDR395w/SXM1 as a potential karyopherin on the basis of limited sequence similarity to known karyopherins. From yeast cytosol, we isolated Sxm1p in complex with several potential import substrates. These substrates included Lhp1p, the yeast homologue of the human autoantigen La that has recently been shown to facilitate maturation of pre-tRNA, and three distinct ribosomal proteins, Rpl16p, Rpl25p, and Rpl34p. Further, we demonstrate that Lhp1p is specifically imported by Sxm1p. In the absence of Sxm1p, Lhp1p was mislocalized to the cytoplasm. Sxm1p and Lhp1p represent the karyopherin and a cognate substrate of a unique nuclear import pathway, one that operates upstream of a major pathway of pre-tRNA maturation, which itself is upstream of tRNA export in wild-type cells. In addition, through its association with ribosomal proteins, Sxm1p may have a role in coordinating ribosome biogenesis with tRNA processing.