Genetic manipulation of Saccharomyces cerevisiae by use of the LYS2 gene

Using Baker's Yeast to Determine Functions of Novel Wolbachia (and Other Prokaryotic) Effectors

Yeasts are single-celled eukaryotic organisms classified as fungi, mostly in the phylum Ascomycota. Of about 1500 named species, Saccharomyces cerevisiae, also known as baker's yeast, domesticated by humans in the context of cooking and brewing, is a profound genetic tool for exploring functions of novel effector proteins from Wolbachia and prokaryotes in general. Wolbachia is a Gram-negative alpha-proteobacterium that infects up to ~75% of all insects as an obligate intracellular microbe (Jeyaprakash A, Hoy MA, Insect Mol Biol 9:393-405, 2000). Wolbachia's lifestyle presents unique challenges for researchers. Wolbachia cannot be axenically cultured and has never been genetically manipulated. Furthermore, many Wolbachia genes have no known function or well-annotated orthologs in other genomes. Yet given the effects of Wolbachia on host phenotypes, which have considerable practical applications for pest control, they undoubtedly involve secreted effector proteins that interact with host gene products. Studying these effectors is challenging with Wolbachia's current genetic limitations. However, some of the constraints to working with Wolbachia can be overcome by expressing candidate proteins in S. cerevisiae. This approach capitalizes on yeast's small genome (~6500 genes), typical eukaryotic cellular organization, and the sophisticated suite of genetic tools available for its manipulation in culture. Thus, yeast can serve as a powerful mock eukaryotic host background to study Wolbachia effector function. Specifically, yeast is used for recombinant protein expression, drug discovery, protein localization studies, protein interaction mapping (yeast two-hybrid system), modeling chromosomal evolution, and examining interactions between proteins responsible for complex phenotypes in less tractable prokaryotic systems. As an example, the paired genes responsible for Wolbachia-mediated cytoplasmic incompatibility (CI) encode novel proteins with limited homology to other known proteins, and no obvious function. This article details how S. cerevisiae was used as an initial staging ground to explore the molecular basis of one of Wolbachia's trademark phenotypes (CI).

Expression of Lectins in Heterologous Systems

Lectins are proteins that have the ability to recognize and bind in a reversible and specific way to free carbohydrates or glycoconjugates of cell membranes. For these reasons, they have been extensively used in a wide range of industrial and pharmacological applications. Currently, there is great interest in their production on a large scale. Unfortunately, conventional techniques do not provide the appropriate platform for this purpose and therefore, the heterologous production of lectins in different organisms has become the preferred method in many cases. Such systems have the advantage of providing better yields as well as more homogeneous and better-defined properties for the resultant products. However, an inappropriate choice of the expression system can cause important structural alterations that have repercussions on their biological activity since the specificity may lay in their post-translational processing, which depends largely on the producing organism. The present review aims to examine the most representative studies in the area, exposing the four most frequently used systems (bacteria, yeasts, plants and animal cells), with the intention of providing the necessary information to determine the strategy to follow in each case as well as their respective advantages and disadvantages.

Purification and characterization of YACs containing large inserts

This unit provides protocols for characterizing DNA segments cloned in YACs and for purifying YACs from yeast chromosomes. The first basic protocol describes Southern blotting and partial-digest restriction analysis of YACs. These methods are useful for determining the size and complexity of the cloned insert DNA, the presence and location of particular restriction sites or sequences, and even the species of origin of the insert DNA (indicated by hybridization to species-specific repetitive elements such as Alu repeats). The second basic protocol describes gel purification of YACs for use in procedures requiring pure YAC DNA, such as mammalian-cell transformation and subcloning into smaller insert vectors. The third basic protocol details characterizing and analyzing YACs: in vivo fragmentation via homologous recombination with specialized fragmentation vectors containing specific probe sequences or repetitive elements, followed by Southern blotting with YAC- and human-derived probes.

Site-directed mutational analysis of the novel catalytic domains of alpha-aminoadipate reductase (Lys2p) from Candida albicans

The alpha-aminoadipate reductase, a novel enzyme in the alpha-aminoadipic acid pathway for the biosynthesis of lysine in fungi, catalyzes the conversion of alpha-aminoadipic acid to alpha-aminoadipic-delta-semialdehyde in the presence of ATP, NADPH and MgCl(2). This reaction requires two distinct gene products, Lys2p and Lys5p. In the presence of CoA, Lys5p posttranslationally activates Lys2p for the alpha-aminoadipate reductase activity. Sequence alignments indicate the presence of all functional domains required for the activation, adenylation, dehydrogenation and alpha-aminoadipic acid binding in the Lys2p. In this report we present the results of site-directed mutational analysis of the conserved amino acid residues in the catalytic domains of Lys2p from the pathogenic yeast Candida albicans. Mutants were generated in the LYS2 sequence of pCaLYS2SEI by PCR mutagenesis and expressed in E. coli BL21 cells. Recombinant mutants and the wild-type Lys2p were analyzed for their alpha-aminoadipate reductase activity. Substitution of threonine 416, glycine 418, serine 419, and lysine 424 of the adenylation domain (TXGSXXXXK, residues 416-424) resulted in a significant reduction in alpha-aminoadipate reductase activity compared to the unmutagenized Lys2p control. Similarly replacement of glycine 978, threonine 980, glycine 981, phenylalanine 982, leucine 983 and glycine 984 of the NADPH binding domain (GXTGFLG, residues 978-984) caused a drastic decrease in alpha-aminoadipate reductase activity. Finally, substitution of histidine 460, aspartic acid 461, proline 462, isoleucine 463, glutamine 464, arginine 465, and aspartic acid 466 of the putative alpha-aminoadipic acid binding domain (HDPIQRD, residues 460-466) resulted in a highly reduced alpha-aminoadipate reductase activity. These results confirm the hypothesis that specific amino acid residues in highly conserved catalytic domains of Lys2p are essential for the alpha-aminoadipate reductase activity.

Yeast cloning vectors and genes

This unit describes some of the most commonly used yeast vectors, as well as the cloned yeast genes that form the basis for these plasmids. Yeast vectors can be grouped into five general classes, based on their mode of replication in yeast: YIp, YRp, YCp, YEp, and YLp plasmids. With the exception of the YLp plasmids (yeast linear plasmids), all of these plasmids can be maintained in E. coli as well as in S. cerevisiae and thus are referred to as shuttle vectors. The nomenclature of different classes of yeast vectors, as well as details about their mode of replication in yeast are discussed.

Overlapping functions of the yeast oxysterol-binding protein homologues

The Saccharomyces cerevisiae genome encodes seven homologues of the mammalian oxysterol-binding protein (OSBP), a protein implicated in lipid trafficking and sterol homeostasis. To determine the functions of the yeast OSBP gene family (OSH1-OSH7), we used a combination of genetics, genomics, and sterol lipid analysis to characterize OSH deletion mutants. All 127 combinations and permutations of OSH deletion alleles were constructed. Individual OSH genes were not essential for yeast viability, but the elimination of the entire gene family was lethal. Thus, the family members shared an essential function. In addition, the in vivo depletion of all Osh proteins disrupted sterol homeostasis. Like mutants that affect ergosterol production, the viable combinations of OSH deletion alleles exhibited specific sterol-related defects. Although none of the single OSH deletion mutants was defective for growth, gene expression profiles revealed that each mutant had a characteristic molecular phenotype. Therefore, each gene performed distinct nonessential functions and contributed to a common essential function. Our findings indicated that OSH genes performed a multitude of nonessential roles defined by specific subsets of the genes and that most shared at least one essential role potentially linked to changes in sterol lipid levels.

High-level rearrangement and transcription of yeast artificial chromosome-based mouse Ig kappa transgenes containing distal regions of the contig

The mouse Ig kappa L chain gene locus has been extensively studied, but to date high-level expression of germline transgenes has not been achieved. Reasoning that each end of the locus may contain regulatory elements because these regions are not deleted upon V kappa-J kappa joining, we used yeast artificial chromosome-based techniques to fuse distal regions of the contig to create transgene miniloci. The largest minilocus (290 kb) possessed all members of the upstream V kappa 2 gene family including their entire 5' and 3' flanking sequences, along with one member of a downstream V kappa 21 gene family. In addition, again using yeast artificial chromosome-based technology, we created Ig kappa miniloci that contained differing lengths of sequences 5' of the most distal V kappa 2 gene family member. In transgenic mice, Ig kappa miniloci exhibited position-independent and copy number-dependent germline transcription. Ig kappa miniloci were rearranged in tissue and developmental stage-specific manners. The levels of rearrangement and transcription of the distal and proximal V kappa gene families were similar to their endogenous counterparts and appeared to be responsive to allelic exclusion, but were differentially sensitive to numerous position effects. The minilocus that contained the longest 5' region exhibited significantly greater recombination of the upstream V kappa 2 genes but not the downstream V kappa 21 gene, providing evidence for a local recombination stimulating element. These results provide evidence that our miniloci contain nearly all regulatory elements required for bona fide Ig kappa gene expression, making them useful substrates for functional analyses of cis-acting sequences in the future.

Cloning and characterization of the Saccharomyces cerevisiae LYS7 gene: evidence for function outside of lysine biosynthesis

The Saccharomyces cerevisiae LYS7 gene has been cloned based on its genetic map position and complementation of a lys7 mutant. The 1453-bp sequence contains an open reading frame (ORF) that predicts a unique 249 amino acid (aa) protein. A Northern blot experiment demonstrated that LYS7 transcription was not regulated by lysine-specific or general aa control mechanisms. To investigate the effects of total loss of LYS7 function, we created a complete deletion of the gene and introduced this allele into wild-type yeast. The lys7 delta mutant requires lysine and simultaneously displays an array of phenotypes that include pH and temperature sensitivity. The pleiotropic phenotypes of the lys7 delta mutant and the constitutive transcription pattern are at odds with the hypothesis that Lys7p functions solely in the lysine biosynthesis pathway.

Isolation of an 800 kb contiguous DNA fragment encompassing a 3.5-cM region of chromosome 1 in Arabidopsis using YAC clones

The apetala1 mutation of Arabidopsis affects floral meristem identity and the development of sepal and petal primordia of the flower. We mapped the available RFLP markers on chromosome 1 that are in the general vicinity of apetala1 on a fine structure map and then chose the closest RFLP as a starting point for contiguous DNA (contig) generation. We report here a contig of about 800 kilobases (kb) that spans a 3.5 cM region of chromosome 1. We used genomic libraries of Arabidopsis prepared in yeast artificial chromosome (YAC) vectors and the detailed characterization of 19 YACs is reported. RFLPs displayed by the end fragments from the walk were mapped to align and correlate the genetic and physical maps for this region of chromosome 1. In this segment of the genome, 1 cM corresponds to a little over 200 kb of physical distance.

Molecular properties of the lys1+ gene and the regulation of alpha-aminoadipate reductase in Schizosaccharomyces pombe

The alpha-aminoadipate pathway for the biosynthesis of lysine is unique to fungi. Molecular properties of the cloned lys1+ gene and the regulation of the encoded alpha-aminoadipate reductase (AAR) were investigated in the fission yeast Schizosaccharomyces pombe. A 5.2-kb HindIII-EcoRI fragment of S. pombe DNA, containing a functional lys1+ gene and a promoter, was subcloned to make the 10.7-kb plasmid pLYS1H. A nested 1.778-kb HindIII-EcoRI DNA fragment that complemented the lys1-131 mutant phenotype was sequenced from the plasmid pLYS1D, and shown to contain an open reading frame (ORF) of 470 amino acids, preceded by putative POLII promoter elements (TATA and CCAAT box elements, and two potential yeast GCN4-binding motifs) within 368 bp upstream of the start codon. This ORF shared with the corresponding region of the isofunctional AAR of Saccharomyces cerevisiae 49% amino-acid identity (62% similarity) overall, within which were smaller regions of marked sequence conservation. One such region coincided (95% identity) with a putative AMP-binding domain motif identified in the AAR of S. cerevisiae. In wild-type S. pombe, AAR activity from cells grown in lysine-supplemented minimal or YEPD media was less than the activity of cells grown in minimal medium. The AAR of S. pombe was more sensitive to feedback inhibition by lysine in vitro than the AAR of S. cerevisiae. These results show the effects of extensive evolutionary divergence on the structure and expression of a pivotal enzyme in the alpha-aminoadipate pathway. Presumably, delineated regions of strong sequence conservation correspond to discrete domains essential to AAR function.

Gene PSO5 of Saccharomyces cerevisiae, involved in repair of oxidative DNA damage, is allelic to RAD16

The pos5-1 mutation renders Saccharomyces cerevisiae cells sensitive to DNA-damaging agents. We have isolated plasmids from a S. cerevisiae genomic library capable of restoring wild-type levels of 254-nm ultraviolet light sensitivity of the pso5-1 mutant. DNA sequence analysis revealed that the complementing activity resides in RAD16, a gene involved in excision repair. Tetrad analysis showed that PSO5, like RAD16, is tightly linked to LYS2 on chromosome II. Moreover, allelism between the pso5-1 and rad16 mutants was demonstrated by the comparison of mutagen sensitivity phenotypes, complementation tests, and by meiotic analysis. The cloned RAD16 gene was capable of restoring wild-type resistance of the pso5-1 mutant to H2O2 and photoactivated 3-carbethoxypsoralen, both treatments generating oxidative stress-related DNA damage. This indicates that RAD16/PSO5 might also participate in the repair of oxidative base damage.

Allele shuffling: conjugational transfer, plasmid shuffling and suppressor analysis in Saccharomyces cerevisiae

Trans-acting suppressor analysis represents a powerful genetic technique capable of revealing interactions among biochemical pathways in vivo. Suppressor characterization in Saccharomyces cerevisiae has traditionally utilized meiotic segregation for the requisite manipulation of strain genotypes. Meiotic segregation is not compatible with all yeast genotypes and can be prohibitively labor intensive when examining large collections of suppressors. To facilitate rapid phenotypic analysis of suppressor mutations, we have devised a novel genetic strategy called 'allele shuffling'. This plasmid-based method should in principle identify allele-specific, allele-dependent and bypass suppressors. A centromere vector (YCp) was developed that can be directly transferred from Escherichia coli to yeast via 'trans-kingdom' conjugation. Suppressors of a thermolabile cdc23 allele, cdc23-39, were isolated in the background of a yeast host strain harboring the mutant cdc23-39 gene positioned on a counterselectable plasmid. CDC23 or cdc23-39 genes cloned into a mobilizable YCp vector were then transferred directly from E. coli cultures to each suppressed yeast strain on the surfaces of agar plates. Plasmid shuffling of the cdc23-39 allele transconjugants segregated away the original cdc23-39 gene present during mutagenesis, allowing the intra- or extragenic nature of suppression to be determined. Phenotypes (if any) produced by suppressor mutations were revealed in those transconjugants receiving the wild-type CDC23-containing episome. The allele shuffling method should be generally applicable to the analysis of suppressors of any essential yeast gene.

A test of a counting model for chiasma interference

According to the model of FOSS, LANDE, STAHL and STEINBERG, chiasma interference is a reflection of the requirement for crossovers to be separated by an organism-specific number of potential conversion events without associated crossovers. This model predicts that tetrads with close double crossovers should be enriched for conversion events that themselves are not associated with crossing over. We tested this prediction in Saccharomyces cerevisiae and found it to be unfulfilled.

Germinal transpositions of the maize element Dissociation from T-DNA loci in tomato

We have analyzed the pattern of germinal transpositions of artificial Dissociation (Ds) transposons in tomato. T-DNA constructs carrying Ds were transformed into tomato, and the elements were trans-activated by crossing to lines transformed with a stabilized Activator (sAc) that expressed the transposase gene. The sAc T-DNA carried a GUS gene to monitor its segregation. The Ds elements were inserted in a marker gene so that excision from the T-DNA could be monitored. The Ds elements also carried a genetic marker that was intended to be used for reinsertion selection of the elements after excision. Unfortunately, this gene was irreversibly inactivated on crossing to sAc. Germinal excision frequencies of Ds averaged 15-40%, but there was large variation between and within plants. Southern hybridization analysis of stable transposed Ds elements indicated that although unique transpositions predominate, early transposition events can lead to large clonal sectors in the germline of developing plants and to sibling offspring carrying the same transposition event. Multiple germinal transpositions from three different loci were examined for uniqueness, and 15 different transpositions were identified from each of three T-DNA loci that carried a single independent Ds. These were mapped relative to the donor T-DNA loci, and for each locus 70-80% of the transposed elements were closely linked to the donor site.

Functional consequences in yeast of single-residue alterations in a consensus calmodulin

A synthetic gene encoding a ‘consensus’ calmodulin (synCaM) was able to substitute for the Saccharomyces cerevisiae calmodulin gene (CMDI), even though synCaM is only 60% identical in primary amino acid sequence to yeast Cmd1. Twelve different synCaM mutants were also expressed in yeast. Seven of the 12 mutant synCaMs supported germination and growth of Cmd1-deficient spores. Five of the 12 mutant synCaMs were incapable of supporting germination of Cmd1-deficient spores and, of these, four were also incapable of supporting vegetative growth of Cmd1-deficient haploid cells. The five nonfunctional synCaM mutants were expressed at levels equivalent to, or higher than, the seven synCaM mutants that were able to substitute for Cmd1; thus, the inability to function was not simply due to inadequate expression or rapid degradation. All nonfunctional synCaM mutants shared a single charge reversal mutation in the central helix (E84K), which was found to be sufficient to confer the lethal phenotype. The ability of another mutant synCaM (S101F) to support growth of Cmd1-deficient cells was dependent on cell ploidy. Another mutant (K115Y) supported spore germination and vegetative growth, but not meiosis and sporulation. The terminal phenotype of cells lacking a functional calmodulin included a dramatic accumulation of polymerized microtubules.

Analysis of the chromosomal distribution of transposon-carrying T-DNAs in tomato using the inverse polymerase chain reaction

We are developing a system for isolating tomato genes by transposon mutagenesis. In maize and tobacco, the transposon Activator (Ac) transposes preferentially to genetically linked sites. To identify transposons linked to various target genes, we have determined the RFLP map locations of Ac- and Dissociation (Ds)-carrying T-DNAs in a number of transformants. T-DNA flanking sequences were isolated using the inverse polymerase chain reaction (IPCR) and located on the RFLP map of tomato. The authenticity of IPCR reaction products was tested by several criteria including nested primer amplification, DNA sequence analysis and PCR amplification of the corresponding insertion target sequences. We report the RFLP map locations of 37 transposon-carrying T-DNAs. We also report the map locations of nine transposed Ds elements. T-DNAs were identified on all chromosomes except chromosome 6. Our data revealed no apparent chromosomal preference for T-DNA integration events. Lines carrying transposons at known map locations have been established which should prove a useful resource for isolating tomato genes by transposon mutagenesis.

Para-aminobenzoate synthase gene of Saccharomyces cerevisiae encodes a bifunctional enzyme

The Saccharomyces cerevisiae gene for para-aminobenzoate (PABA) synthase has been identified based upon its ability to confer sulfonamide resistance when present on a multicopy episomal vector. The 3840 bp DNA sequence fragment reported here contains a 2199 bp open reading frame encoding a 733 amino acid protein with similarity to the two components of PABA synthase described for prokaryotes (Escherichia coli PabA and PabB), suggesting that PABA synthase is bifunctional in yeast. The cloned sequence was confirmed to be PABA synthase by gene disruption. Chromosome gel analysis places the gene for PABA synthase on chromosome XIV.

Time-dependent mitotic recombination in Saccharomyces cerevisiae

The time-dependent appearance of prototrophic recombinants between heterologously located artificial repeats has been studied in Saccharomyces cerevisiae. While initial prototrophic colony numbers from independent cultures were highly variable, additional recombinants were found to arise daily at roughly constant rates irrespective of culture. These late-appearing recombinants could be accounted for neither by detectable growth on the selective media nor by delayed appearance of recombinants present at the time of selective plating. Significantly, at no time did the distributions of recombinants fully match those expected according to the Luria-Delbruck model and, in fact, after the first day, the distributions much more closely approximated a Poisson distribution. Prototrophic recombinants accumulated not only on the relevant selective medium, but also on media unrelated to the acquired prototrophy.

Expression of the Saccharomyces cerevisiae RAD50 gene during meiosis: steady-state transcript levels rise and fall while steady-state protein levels remain constant

In Saccharomyces cerevisiae, the RAD50 gene is required for repair of X-ray and MMS-induced DNA damage during vegetative growth, and for synaptonemal complex formation and genetic recombination during meiosis. We show below that the RAD50 gene encodes major and minor transcripts of 4.2 and 4.6 kb in length which differ primarily at their 5' ends. Steady-state levels of both RAD50 transcripts increase coordinately during meiosis, reaching maximal levels midway through meiotic prophase, about 3 or 4 h after transfer of cells to sporulation medium. The 5' ends of the major RAD50 transcript in both meiotic and vegetative cells map to the same cluster of sites approximately 20 bp upstream of the amino-terminal ATG of the RAD50 coding sequence. We conclude that the increased RAD50 transcript level observed during meiosis does not reflect utilization of a new promoter. In contrast, steady-state levels of Rad50 protein do not increase during meiosis. Thus, changes in RAD50 transcript levels are not necessarily accompanied by commensurate changes in Rad50 protein levels. Possible explanations are considered.

Physical and functional characterization of the cloned lys1+ gene of Schizosaccharomyces pombe

The alpha-aminoadipate pathway for the biosynthesis of lysine is present in yeast and other higher fungi. The lys2 and lys5 mutants of Saccharomyces cerevisiae as well as the lys1- and lys7-mutants of Schizosacharomyces pombe are blocked at the alpha-aminoadipate reductase step of this pathway. The cloned lys1+ gene in the plasmid pLYS1 isolated from a S. pombe genomic library complemented lys1-mutant of S. pombe. The cloned LYS2 gene in the plasmid YEp620 and the LYS5 gene in the plasmid pSC5 of S. cerevisiae exhibited heterologous complementation of lys1- and lys7-mutants, respectively, of S. pombe. The homologous lys1+ transformed cells exhibited five fold higher alpha-aminoadipate reductase activity while the heterologous lys1+ and lys7+ transformed cells exhibited much less activity than the wild type cells. The DNA insert of the plasmid pLYS1 was determined to be 16.7 kb long and the lys1+ gene has been subcloned within a 9.1 kb Clal-Clal DNA insert of the recombinant plasmids pLYS1B and pLYS1C. The restriction pattern for 12 enzymes of the 9.1 kb DNA insert, (Apal, Aval, BamHI, Clal, EcoRI, EcoRV, HindIII, Hpal, Pstl, Pvull, Sphl, and Xbal), exhibited no obvious similarity to that of the LYS2 gene of S. cerevisiae. A 1.7 kb EcoRI-HindIII DNA fragment of pLYS1B and pLYS1C complemented the lys1-131 mutation in an integrative transformation. Although the lys1+ gene of S. pombe is isofunctional to the LYS2 gene of S. cerevisiae, the restriction sites, and expression of these two genes exhibited considerable divergence.

Incorporation of copy-number control elements into yeast artificial chromosomes by targeted homologous recombination

We have developed a pair of vectors for exchanging yeast artificial chromosome (YAC) arms by targeted homologous recombination. These conversion vectors allow the introduction of copy-number control elements into YACs constructed with pYAC4 or related vectors. YACs modified in this way provide an enriched source of DNA for genetic or biochemical studies. A LYS2 gene on the conversion vector provides a genetic selection for the modified YACs after transformation with appropriately prepared vector. A background of Lys+ clones that do not contain modified YACs is also present. However, clones with converted YACs can be distinguished from this background by counter-screening for loss of the original p YAC4 TRP1 arm (Trp- phenotype). The elimination of yeast replication origins (ARS elements) from the conversion vectors increased the frequency of Lys+ Trp- clones, but resulted in weaker amplification. Several YACs have been converted with these vectors, and the fate of the transformed DNA and of the resident YAC DNA has been systematically investigated.

Calcineurin mediates inhibition by FK506 and cyclosporin of recovery from alpha-factor arrest in yeast

The structurally unrelated immunosuppressants FK506 and cyclosporin A (CsA) act similarly, inhibiting a Ca(2+)-dependent signal required for interleukin-2 transcription and T-cell activation. Each drug binds to its cytosolic receptor, FKBP-12 and cyclophilin, respectively, and the drug-receptor complexes inhibit the Ca2+/calmodulin-dependent protein phosphatase, calcineurin. In yeast, calcineurin has been implicated in recovery from alpha-mating factor arrest. Here we show that FK506 bound to yeast FKBP-12 appears to form a complex with yeast calcineurin. Moreover, recovery from mating factor arrest is highly sensitive to FK506 or CsA, and this sensitivity requires the presence of FKBP-12 or cyclophilin, respectively. These results define a key physiological target of an FK506- and CsA-sensitive signal pathway in yeast, suggest a high degree of mechanistic conservation with mammalian cells, and indicate that further examination of the yeast system should provide insight into the same process in T cells.

An examination of adaptive reversion in Saccharomyces cerevisiae

Reversion to Lys+ prototrophy in a haploid yeast strain containing a defined lys2 frameshift mutation has been examined. When cells were plated on synthetic complete medium lacking only lysine, the numbers of Lys+ revertant colonies accumulated in a time-dependent manner in the absence of any detectable increase in cell number. An examination of the distribution of the numbers of early appearing Lys+ colonies from independent cultures suggests that the mutations to prototrophy occurred randomly during nonselective growth. In contrast, an examination of the distribution of late appearing Lys+ colonies indicates that the underlying reversion events occurred after selective plating. No accumulation of Lys+ revertants occurred when cells were starved for tryptophan, leucine or both lysine and tryptophan prior to plating selectively for Lys+ revertants. These results indicate that mutations accumulate more frequently when they confer a selective advantage, and are thus consistent with the occurrence of adaptive mutations in yeast.

Identification of RAD16, a yeast excision repair gene homologous to the recombinational repair gene RAD54 and to the SNF2 gene involved in transcriptional activation

The RAD54 gene of Saccharomyces cerevisiae is involved in the recombinational repair of DNA damage. The predicted amino acid sequence of the RAD54 protein shows significant homologies with the yeast SNF2 protein, which is required for the transcriptional activation of a number of diversely regulated genes. These proteins are 31% identical in a 492-amino acid region that includes presumed nucleotide and Mg2+ binding sites. We noted previously that the SNF2 protein also shares homology with a partial open reading frame (ORF) that was reported with the sequence of an adjacent gene. This ORF also shares homology with the RAD54 protein. To test whether this ORF is involved in transcriptional activation or DNA repair, yeast strains deleted for part of it have been isolated. These strains do not show a Snf-like phenotype, but they are UV sensitive. This gene has been identified as RAD16, a gene involved in the excision repair of DNA damage. Analysis of the rad16 deletion mutations indicates that RAD16 encodes a non-essential function and is not absolutely required for excision repair. Outside the region of homology to RAD54 and SNF2, the predicted RAD16 protein contains a novel cysteine-rich motif that may bind zinc and that has been found recently in eleven other proteins, including the yeast RAD18 protein. The homologies between RAD16, RAD54 and SNF2 are also shared by several additional, recently isolated yeast and Drosophila genes.

Minimal extent of homology required for completion of meiotic recombination in Saccharomyces cerevisiae

The minimal length of contiguous homology required for successful completion of meiotic recombination was investigated by using heterologous insertions to delimit homologous segments of chromosome III in the yeast Saccharomyces cerevisiae. Constructs created in vitro by insertion of selectable markers into the LEU2 locus were transplaced into haploid strains, which were then mated to create diploids containing pairs of insertion heterologies at various distances. Analysis of the meiotic products from these diploids revealed a gradient in the frequency of both reciprocal and nonreciprocal recombination declining monotonically from the 5' end of LEU2. Both types of event were found to be restricted by the presence of the insertion heterologies. The spo13 single division meiosis was exploited to develop a plating assay in which LEU2 diploid spores containing reciprocally recombinant strands derived from events occurring completely within the interval flanked by the insertion heterologies were selected by random spore methods. Reciprocal recombination frequencies measured with this assay decreased linearly with extent, extrapolating to a minimal homology requirement of 150-250 nucleotides. When homology was most severely restricted, unexpected flanking marker configurations among reciprocal recombinants within LEU2 demonstrated the occurrence of complex recombination events. In addition to detecting reciprocal recombinants, the system is capable of measuring the probability that a non-reciprocal recombination event will have one end-point between the heterologous inserts and the other lying outside the interval. The minimal length of homology required for this aspect of recombination was found to be 25-60 nucleotides.

Physical and biochemical characterization of the cloned LYS5 gene required for alpha-aminoadipate reductase activity in the lysine biosynthetic pathway of Saccharomyces cerevisiae

The LYS5 and LYS2 genes of Saccharomyces cerevisiae are required for the synthesis of alpha-aminoadipate reductase in the lysine pathway. The LYS5 gene, originally cloned as a DNA insert of the plasmid pSC5, has been subcloned on a 3.2 kb SphI-Sau3AI DNA fragment of the recombinant plasmid pSR7. An internal 2.1 kb HpaI-HpaI DNA fragment of the subclone, upon Southern hybridization, exhibits homology with HpaI-restricted wild-type S. cerevisiae genomic DNA. The lys5+ transformants exhibited alpha-aminoadipate reductase activity similar to that of wild-type cells. S1 nuclease analysis localizes the transcription initiation site relative to the detailed restriction map, and reveals the direction of transcription, as well as the transcript size of the LYS5 gene which can be no greater than 1.65 kb. From this it is estimated that the encoded polypeptide is appreciably smaller than the 4 kb LYS2 gene product. These results provide a physical and biochemical characterization of the cloned LYS5 gene. Based on these observations, it is concluded that the LYS5 gene encodes a relatively small polypeptide of the large heteropolymeric alpha-aminoadipate reductase.

The YDp plasmids: a uniform set of vectors bearing versatile gene disruption cassettes for Saccharomyces cerevisiae

The YDp plasmids (Yeast Disruption plasmids) are pUC9 vectors bearing a set of yeast gene disruption cassettes, all uniform in structure and differing only in the selectable marker used (HIS3, LEU2, LYS2, TRP1 or URA3). The markers, surrounded by translational termination codons, are embedded in the slightly modified sequence of the pUC9 multiple cloning sites.

PRP16 is an RNA-dependent ATPase that interacts transiently with the spliceosome

The assembly of the spliceosome is an ATP-dependent process. The splicing factor PRP16 contains variations of several motifs that define the eIF-4A-like ATP-dependent RNA helicase family. The protein has now been purified and shown to exhibit RNA-dependent ATPase activity. PRP16 is required specifically for the second catalytic step of the splicing reaction in vitro. This function requires ATP binding and/or hydrolysis, which appears to be concomitant with release of the protein from the spliceosome. PRP16 may be the prototype for a set of splicing factors which use ATP to drive a cycle of conformational changes.

Nucleotide sequence of the LYS2 gene of Saccharomyces cerevisiae: homology to Bacillus brevis tyrocidine synthetase 1

The Saccharomyces cerevisiae LYS2 gene, which encodes alpha-aminoadipate reductase, an essential enzyme in the yeast lysine biosynthetic pathway, has been sequenced. A large open reading frame (ORF) has been identified which can specify a 1392-amino acid protein with a deduced Mr of 155,344. A DNA database search using the translated LYS2 ORF as a probe has revealed significant aa sequence homology to the Bacillus brevis enzyme tyrocidine synthetase 1.

Identification of a gene necessary for cell cycle arrest by a negative growth factor of yeast: FAR1 is an inhibitor of a G1 cyclin, CLN2

alpha factor is a negative growth factor and differentiation factor that induces G1 arrest and increases transcription of mating genes in S. cerevisiae a cells. We have identified a gene, FAR1 (for "factor arrest"), which is necessary for cell cycle arrest but not for other responses to alpha factor: far1- mutants are insensitive to arrest despite having an intact signal transduction pathway. FAR1 is a nonessential gene whose expression is induced 4- to 5-fold in a cells by alpha factor. The sequence of FAR1 indicates no significant similarities to known proteins. A null mutation in the CLN2 gene, which codes for a G1 cyclin, reverses the effect of a far1 null mutation: far1- cln2- strains arrest in response to alpha factor. We thus propose that FAR1 contributes to cell cycle arrest by inhibiting CLN2. The behavior of far1- cln2- strains indicates that products other than FAR1 are responsible for inhibiting the other G1 cyclins, CLN1 and CLN3.

Distance-independence of mitotic intrachromosomal recombination in Saccharomyces cerevisiae

Many genetic studies have shown that the frequency of homologous recombination depends largely on the distance in which recombination can occur. We have studied the effect of varying the length of duplicated sequences on the frequency of mitotic intrachromosomal recombination in Saccharomyces cerevisiae. We find that the frequency of recombination resulting in the loss of one of the repeats and the intervening sequences reaches a plateau when the repeats are short. In addition, the frequency of recombination to correct a point mutation contained in one of these repeats is not proportional to the size of the duplication but rather depends dramatically on the location of the mutation within the repeated sequences. However, the frequency of mitotic interchromosomal reciprocal recombination is dependent on the distance separating the markers. The difference in the response of intrachromosomal and interchromosomal mitotic recombination to increasing lengths of homology may indicate there are different rate-limiting steps for recombination in these two cases. These findings have important implications for the maintenance and evolution of duplicated sequences.

Manipulating yeast genome using plasmid vectors

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.

Cloning of a new bidirectionally selectable marker for Aspergillus strains

Mutants that lack adenosine triphosphate sulfurylase (ATPsase; EC 2.7.7.4) are unable to use sulfate as sole source of sulfur and are also resistant to selenate. These mutants, denoted sC-, are readily obtained from any strain of Aspergillus niger or Aspergillus nidulans by the strong selection for selenate resistance. We have cloned the gene encoding ATPsase from A. nidulans by complementation of an sC mutant strain of A. nidulans with a gene library and show that plasmids containing this gene transform both A. niger and A. nidulans sC- strains, restoring their ability to grow on sulfate as sole sulfur source. The fact that strong selection for either sC+ or sC- can be applied provides a simple way of delivering genetically engineered constructs to any strain of A. niger including strains of industrial importance. In addition, this system is useful for gene replacements and other genomic DNA manipulations in Aspergillus species.

Galactose as a gratuitous inducer of GAL gene expression in yeasts growing on glucose

The promoters of the highly expressed and stringently regulated GAL genes of Saccharomyces cerevisiae, are useful for expressing proteins in this organism. However, two problems complicate their use. First, because growth on glucose causes prolonged repression of GAL expression, cells are most rapidly induced after growth on nonfermentable carbon sources, conditions which usually support poor growth. Second, because the inducer of the GAL genes (galactose) also serves as a carbon source, the level of inducer is continually diminishing during growth of a Gal+ strain, which may lead to reduced GAL expression. To solve the first problem, we have employed strains that carry the reg1-501 mutation, which eliminates glucose repression of GAL expression. This gene has been shown to be located on the right arm of chromosome IV, distal but tightly linked to the TRP1 gene. We demonstrate that expression from GAL promoters is efficiently and rapidly induced in these reg1 strains by the addition of galactose to a culture growing in glucose medium. Levels of galactose as low as 0.02% can be used to obtain a 1500-fold induction of gene expression from GAL promoters in this strain. To surmount the second problem, we have used a gal1 mutant, deficient in the enzyme that catalyzes the first step of galactose utilization. We show that high levels of expression from GAL promoters are achieved rapidly in these mutants, for which galactose is a gratuitous inducer.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning and physical characterization of linked lysine genes (lys4, lys15) of Saccharomyces cerevisiae

The plasmid pSC4 which carries a 7.8 kb yeast DNA insert at the BamHI site of the Vector YEp13, complemented simultaneously MO-59-13c lys4, LU75 lys15 and LU32 lys4lys15 (double) mutations of Saccharomyces cerevisiae. The 1.9 kb BamHI-XbaI DNA insert of the subclone pSO51 complemented the LU75 lys15 mutation. The 2.8 kb Xhol-XhoI DNA insert of the pSO52 subclone, like pSC4, complemented all three mutations. The 1.9 kb BamHI-XbaI DNA and the 2.8 kb Xhol-XhoI DNA were 100 bp apart in the pSC4 DNA insert and exhibited no homology with each other upon Southern hybridization. The 1.9 kb BamHI-XbaI DNA insert exhibited homology with the pSC4 and pSO51 DNA as well as the genomic DNA of MO-59-13c lys4, LU75 lys15, LU32 lys4lys15, and RC1 (LYS) when digested with appropriate restriction enzymes. The 2.8 kb XhoI-XhoI DNA insert exhibited homology with the pSC4 and pSO52 DNA as well as MO-59-13c lys4, LU75 lys15, LU32 lys4lys15, and RC1 (LYS) genomic DNA, when digested with XhoI enzyme. The 2.8 kb DNA probe also hybridized with ply(A)+ RNA from RC1 and lys4+ transformant but not that from MO-59-13c lys4 mutant.

Properties of revertants of lys2 and lys5 mutants as well as alpha-aminoadipate-semialdehyde dehydrogenase from Saccharomyces cerevisiae

alpha-Aminoadipate-semialdehyde dehydrogenase catalyzes the conversion of alpha-aminoadipate to alpha-aminoadipate-semialdehyde in the biosynthetic pathway of lysine in yeasts and molds. Mutants belonging to lys2 and lys5 loci of Saccharomyces cerevisiae lacked the alpha-aminoadipate-semialdehyde dehydrogenase activity. Complementation in vitro was demonstrated by combining the extracts from different lys2 and lys5 mutants. Some of the revertants of lys2 and lys5 mutants exhibited lower specific activity and higher thermolability of alpha-aminoadipate-semialdehyde dehydrogenase than the enzyme from wild-type cells. The enzyme was partially purified from wild-type cells and the molecular weight of the enzyme was estimated on a Sephacryl S-300 column at 180,000. Results from the revertant analysis and in vitro complementation indicated LYS2 and LYS5 as structural genes, each encoding a subunit of this large enzyme.

The MF alpha 1 gene of Saccharomyces cerevisiae: genetic mapping and mutational analysis of promoter elements

The activity and cell-type specificity of the promoter of the MF alpha 1 gene of Saccharomyces cerevisiae were examined by measuring expression of an MF alpha 1-SUC2 gene fusion in MATa, MAT alpha, and MATa/MAT alpha cells. A high level of invertase activity was observed only in MAT alpha cells. Weak expression occurred in MATa cells when the hybrid gene was carried on a multicopy plasmid or on a centromere-containing plasmid, but not when the hybrid gene was integrated at the normal MF alpha 1 locus. Analysis of a set of 5'-deletions of the promoter region of the MF alpha 1-SUC2 gene on the multicopy plasmid indicated that sequences from -354 to -274 upstream of the translational start site were required for high level expression in MAT alpha cells. Smaller internal deletions and insertions within the promoter region of the MF alpha 1-SUC2 gene were inserted into the genome at the normal MF alpha 1 locus. These mutations further delineated four promoter domains important for expression: (1) two 26 bp elements (-365 to -340 and -312 to -287) with imperfect dyad symmetry; (2) a 40 bp segment (-264 to -226) that lies about 120 bp upstream of the TATA box; and (3) the TATA box itself (-128 to -122). The transcriptional start sites of the normal MF alpha 1 promoter and of a mutant lacking the TATA box were determined. The MF alpha 1 locus was mapped to the left arm of chromosome XVI, about 22 cM centromere-proximal to the PEP4 gene.

Cloning and characterization of the CYC8 gene mediating glucose repression in yeast

Mutations in the CYC8 ( = SSN6) gene of Saccharomyces cerevisiae alleviate glucose repression of many glucose-repressible genes. The gene was isolated by screening for complementation of a cyc8 effect on colony morphology. Subclones containing a 5.3-kb SalI-XbaI fragment provided complete complementation. The gene was further localized to 3.5 kb by mapping of the CYC8 mRNA and insertional mutagenesis. Insertion and deletion mutations are viable and produce the same array of phenotypes as point mutations. CYC8 disruptions also had effects on the mating ability and morphology of MAT alpha cells similar to that of tup1 mutations. The nucleotide sequence of a 4866-bp fragment, including CYC8, was determined. One long open reading frame of 966 amino acid predicts a protein of molecular weight 10,7215. The predicted protein is extremely glutamine-rich, with blocks of 16 and 31 glutamines in tandem at the N and C regions, respectively. The CYC8 gene product lacks consensus sequences for DNA-binding domains, suggesting that its function may be different from classical repressor proteins.

Two conserved domains of yeast U2 snRNA are separated by 945 nonessential nucleotides

Yeast U2 snRNA (1175 nucleotides) is six times larger than its mammalian counterpart (188 nucleotides). Using deletion analysis, we show that the molecule can be divided into three phenotypically distinct domains. As expected, the highly conserved 5' domain (approximately 120 nucleotides) is absolutely essential for viability. Surprisingly, however, deletion of the central 945 nucleotides has no effect on growth rate. In contrast, removal of sequences in the 3' terminal 110 nucleotides results in low numbers of slow-growing colonies; these cells contain U2 with altered 3' ends. This domain can be folded into a secondary structure that strongly resembles the 3' terminal stem-loop IV of human U2. We conclude that yeast U2 contains two functionally important elements. While the 5' domain is known to be directly involved in the splicing reaction, the 3' domain may function primarily in the generation of stable small nuclear ribonucleoprotein particles.

Conditional mutants of RPC160, the gene encoding the largest subunit of RNA polymerase C in Saccharomyces cerevisiae

A 18.4-kb fragment of the yeast genome containing the gene of the largest subunit of RNA polymerase C (RPC160) was cloned by hybridization to a previously isolated fragment of that gene. RPC160 maps on chromosome XV, tightly linked but not allelic to the essential gene TSM8740. Temperature sensitive (ts) mutant alleles were constructed by in vitro mutagenesis with NaHSO3 and substituted for the wild-type allele on the chromosome. Four of them were unambiguously identified as rpc160 mutants by failure to complement a fully defective mutation rpc160::URA3. The faithful transcription of a yeast tRNA gene by mutant cell-free extracts is strongly reduced as compared to wild-type. In vivo, the rpc160 mutations specifically affect the synthesis of tRNA in a temperature sensitive way, with comparatively little effect on the synthesis of 5S rRNA and no effect on 5.8S rRNA. An unlinked mutation (pcil-3) suppresses the temperature sensitive phenotype of the rpc160-41 mutation.

Cloning and biochemical characterization of LYS5 gene of Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the functions of two unlinked genes (LYS2 and LYS5) are required for the synthesis of the lysine biosynthetic enzyme, alpha-aminoadipate reductase. The LYS5 gene of S. cerevisiae was cloned by functional complementation of a lys5 mutant, X4004-3A, using a YEp24 plasmid library. The cloned LYS5 gene was contained within a 7.5 kb DNA insert of the recombinant plasmid pSC5. Cloning of LYS5 gene was confirmed by second cycle transformation of a lys5 mutant with the pSC5 plasmid, growth response studies, and plasmid loss experiments with Lys5+ transformants. Analysis of restriction digests of the pSC5 plasmid revealed 3 EcoRI, 5 PvuII, 1 PstI, 1 BglII and 2 HpaI sites in the 7.5 kb insert. A 3.9 kb internal pSC5 fragment hybridized only to the plasmid pSC5, but no homology was observed with LYS2 DNA or the YEp24 vector. The pSC5 transformed Lys5+ cells and the wild-type strain exhibited same level of alpha-aminoadipate reductase activity, whereas lys5 mutant and plasmid-cured transformed strain exhibited none. Lys2+ transformants consistently had five times greater alpha-aminoadipate reductase activity when compared with the wild-type and the Lys5+ transformant. The alpha-aminoadipate reductase activity was repressed in lysine-grown wild-type and Lys5+ transformed cells but not in Lys2+ transformed cells. A Lys2+ and Lys5+ double transformant exhibited higher alpha-aminoadipate reductase activity than lys2+ or lys5+ transformant.

The yeast polyubiquitin gene is essential for resistance to high temperatures, starvation, and other stresses

Conjugation of ubiquitin to intracellular proteins mediates their selective degradation in eukaryotes. In the yeast Saccharomyces cerevisiae, four distinct ubiquitin-coding loci have been described. UBI1, UBI2, and UBI3 each encode hybrid proteins in which ubiquitin is fused to unrelated sequences. The fourth gene, UBI4, contains five ubiquitin-coding elements in a head-to-tail arrangement, and thus encodes a polyubiquitin precursor protein. A precise, oligonucleotide-directed deletion of UBI4 was constructed in vitro and substituted in the yeast genome in place of the wild-type allele. ubi4 deletion mutants are viable as vegetative cells, grow at wild-type rates, and contain wild-type levels of free ubiquitin under exponential growth conditions. However, although ubi4/UBI4 diploids can form four initially viable spores, the two ubi4 spores within the ascus lose viability extremely rapidly, apparently a novel phenotype in yeast. Furthermore, ubi4/ubi4 diploids are sporulation-defective. ubi4 mutants are also hypersensitive to high temperatures, starvation, and amino acid analogs. These three conditions, while diverse in nature, are all known to induce stress proteins. Expression of the UBI4 gene is similarly induced by either heat stress or starvation. These results indicate that UBI4 is specifically required for the resistance of cells to stress, and that ubiquitin is an essential component of the stress response system.