Direct Selection for Mutants with Increased K(+) Transport in Saccharomyces Cerevisiae

Saccharomyces cerevisiae cells containing a deletion of TRK1, the gene encoding the high affinity potassium transporter, retain only low affinity uptake of this ion and consequently lose the ability to grow in media containing low levels (0.2 mM) of potassium. Using a trk1 delta strain, we selected spontaneous Trk+ pseudorevertants that regained the ability to grow on low concentrations of potassium. The revertants define three unlinked extragenic suppressors of trk1 delta. Dominant RPD2 mutations and recessive rpd1 and rpd3 mutations confer increased potassium uptake in trk1 delta cells. Genetic evidence suggests that RPD2 mutations are alleles of TRK2, the putative low affinity transporter gene, whereas rpd1 and rpd3 mutations increase TRK2 activity: (1) RPD2 mutations are closely linked to trk2, and (2) trk2 mutations are epistatic to both rpd1 and rpd3. rpd1 maps near pho80 on chromosome XV and rpd3 maps on the left arm of chromosome XIV, closely linked to kre1.     

Genes Required for Vacuolar Acidity in Saccharomyces Cerevisiae

Mutations that cause loss of acidity in the vacuole (lysosome) of Saccharomyces cerevisiae were identified by screening colonies labeled with the fluorescent, pH-sensitive, vacuolar labeling agent, 6-carboxyfluorescein. Thirty nine vacuolar pH (Vph-) mutants were identified. Four of these contained mutant alleles of the previously described PEP3, PEP5, PEP6 and PEP7 genes. The remaining mutants defined eight complementation groups of vph mutations. No alleles of the VAT2 or TFP1 genes (known to encode subunits of the vacuolar H(+)-ATPase) were identified in the Vph- screen. Strains bearing mutations in any of six of the VPH genes failed to grow on medium buffered at neutral pH; otherwise, none of the vph mutations caused notable growth inhibition on standard yeast media. Expression of the vacuolar protease, carboxypeptidase Y, was defective in strains bearing vph4 mutations but was apparently normal in strains bearing any of the other vph mutations. Defects in vacuolar morphology at the light microscope level were evident in all Vph- mutants. Strains that contained representative mutant alleles of the 17 previously described PEP genes were assayed for vacuolar pH; mutations in seven of the PEP genes (including PEP3, PEP5, PEP6 and PEP7) caused loss of vacuolar acidity.     

Isolation of Mutants Defective in Early Steps of Meiotic Recombination in the Yeast Saccharomyces Cerevisiae

Using a selection based upon the ability of early Rec- mutations (e.g., rad50) to rescue the meiotic lethality of a rad52 spo13 strain, we have isolated 177 mutants. Analysis of 56 of these has generated alleles of the known Rec genes SPO11, ME14 and MER1, as well as defining five new genes: REC102, REC104, REC107, REC113 and REC114. Mutations in all of the new genes appear to specifically affect meiosis; they do not have any detectable mitotic phenotype. Mutations in REC102, REC104 and REC107 reduce meiotic recombination several hundred fold. No alleles of RED1 or HOP1 were isolated, consistent with the proposal that these genes may be primarily involved with chromosome pairing and not exchange.     

Chromatin Assembly Factor I Mutants Defective for PCNA Binding Require Asf1/Hir Proteins for Silencing

Chromatin assembly factor I (CAF-I) is a conserved histone H3/H4 deposition complex. Saccharomyces cerevisiae mutants lacking CAF-I subunit genes (CAC1 to CAC3) display reduced heterochromatic gene silencing. In a screen for silencing-impaired cac1 alleles, we isolated a mutation that reduced binding to the Cac3p subunit and another that impaired binding to the DNA replication protein PCNA. Surprisingly, mutations in Cac1p that abolished PCNA binding resulted in very minor telomeric silencing defects but caused silencing to be largely dependent on Hir proteins and Asf1p, which together comprise an alternative silencing pathway. Consistent with these phenotypes, mutant CAF-I complexes defective for PCNA binding displayed reduced nucleosome assembly activity in vitro but were stimulated by Asf1p-histone complexes. Furthermore, these mutant CAF-I complexes displayed a reduced preference for depositing histones onto newly replicated DNA. We also observed a weak interaction between Asf1p and Cac2p in vitro, and we hypothesize that this interaction underlies the functional synergy between these histone deposition proteins.     

Saccharomyces Cerevisiae Cho2 Mutants Are Deficient in Phospholipid Methylation and Cross-Pathway Regulation of Inositol Synthesis

Five allelic Saccharomyces cerevisiae mutants deficient in the methylation of phosphatidylethanolamine (PE) have been isolated, using two different screening techniques. Biochemical analysis suggested that these mutants define a locus, designated CHO2, that may encode a methyltransferase. Membranes of cho2 mutant cells grown in defined medium contain approximately 10% phosphatidylcholine (PC) and 40-50% PE as compared to wild-type levels of 40-45% PC and 15-20% PE. In spite of this greatly altered phospholipid composition, cho2 mutant cells are viable in defined medium and are not auxotrophic for choline or other phospholipid precursors such as monomethylethanolamine (MME). However, analysis of yeast strains carrying more than one mutation affecting phospholipid biosynthesis indicated that some level of methylated phospholipid is essential for viability. The cho2 locus was shown by tetrad analysis to be unlinked to other loci affecting phospholipid synthesis. Interestingly, cho2 mutants and other mutant strains that produce reduced levels of methylated phospholipids are unable to properly repress synthesis of the cytoplasmic enzyme inositol-1-phosphate synthase. This enzyme was previously shown to be regulated at the level of mRNA abundance in response to inositol and choline in the growth medium. We cloned the CHO2 gene on a 3.6-kb genomic DNA fragment and created a null allele of cho2 by disrupting the CHO2 gene in vivo. The cho2 disruptant, like all other cho2 mutants, is viable, exhibits altered regulation of inositol biosynthesis and is not auxotrophic for choline or MME.     

Saccharomyces cerevisiae Mutants Affected in Vacuole Assembly or Vacuolar H+-ATPase are Hypersensitive to Lead (Pb) Toxicity

Lead is an important environmental pollutant. The role of vacuole, in Pb detoxification, was studied using a vacuolar protein sorting mutant strain (vps16Δ), belonging to class C mutants. Cells disrupted in VPS16 gene, did not display a detectable vacuolar-like structure. Based on the loss of cell proliferation capacity, it was found that cells from vps16Δ mutant exhibited a hypersensitivity to Pb-induced toxicity, compared to wild type (WT) strain. The function of vacuolar H⁺-ATPase (V-ATPase), in Pb detoxification, was evaluated using mutants with structurally normal vacuoles but defective in subunits of catalytic (vma1Δ or vma2Δ) or membrane domain (vph1Δ or vma3Δ) of V-ATPase. All mutants tested, lacking a functional V-ATPase, displayed an increased susceptibility to Pb, comparatively to cells from WT strain. Modification of vacuolar morphology, in Pb-exposed cells, was visualized using a Vma2p-GFP strain. The treatment of yeast cells with Pb originated the fusion of the medium size vacuolar lobes into one enlarged vacuole. In conclusion, it was found that vacuole plays an important role in the detoxification of Pb in Saccharomyces cerevisiae; in addition, a functional V-ATPase was required for Pb compartmentalization.     

Isolation of Degradation-Deficient Mutants Defective in the Targeting of Fructose-1,6-Bisphosphatase into the Vacuole for Degradation in Saccharomyces Cerevisiae

The key regulatory enzyme in the gluconeogenesis pathway, fructose-1,6-bisphosphatase (FBPase), is induced when Saccharomyces cerevisiae are grown in medium containing a poor carbon source. FBPase is targeted to the yeast vacuole for degradation when glucose-starved cells are replenished with fresh glucose. To identify genes involved in the FBPase degradation pathway, mutants that failed to degrade FBPase in response to glucose were isolated using a colony-blotting procedure. These vacuolar import and degradation-deficient (vid) mutants were placed into 20 complementation groups. They are distinct from the known sec, vps or pep mutants affecting protein secretion, vacuolar sorting and vacuolar proteolysis in that they sort CpY correctly and regulate osmotic pressure normally. Despite the presence of FBPase antigen in these mutants, FBPase is completely inactivated in all vid mutants, indicating that the c-AMP-dependent signal transduction pathway and inactivation must function properly in vid mutants. vid mutants block FBPase degradation by accumulating FBPase in the cytosol and also in small vesicles in the cytoplasm. FBPase may be targeted to small vesicles before uptake by the vacuole.     

An Efficient Positive Selection Procedure for the Isolation of Peroxisomal Import and Peroxisome Assembly Mutants of Saccharomyces Cerevisiae

To study peroxisome biogenesis, we developed a procedure to select for Saccharomyces cerevisiae mutants defective in peroxisomal protein import or peroxisome assembly. For this purpose, a chimeric gene was constructed encoding the bleomycin resistance protein linked to the peroxisomal protein luciferase. In wild-type cells this chimeric protein is imported into the peroxisome, which prevents the neutralizing interaction of the chimeric protein with its toxic phleomycin ligand. Peroxisomal import and peroxisome assembly mutants are unable to import this chimeric protein into their peroxisomes. This enables the bleomycin moiety of the chimeric protein to bind phleomycin, thereby preventing its toxicity. The selection is very efficient: upon mutagenesis, 84 (10%) of 800 phleomycin resistant colonies tested were unable to grow on oleic acid. This rate could be increased to 25% using more stringent selection conditions. The selection procedure is very specific; all oleic acid non utilizing (onu) mutants tested were disturbed in peroxisomal import and/or peroxisome assembly. The pas (peroxisome assembly) mutants that have been used for complementation analysis represent 12 complementation groups including three novel ones, designated pas20, pas21 and pas22.     

A Novel Fluorescence-based Genetic Strategy Identifies Mutants of Saccharomyces cerevisiae Defective for Nuclear Pore Complex Assembly

Nuclear pore complexes (NPCs) are large proteinaceous portals for exchanging macromolecules between the nucleus and the cytoplasm. Revealing how this transport apparatus is assembled will be critical for understanding the nuclear transport mechanism. To address this issue and to identify factors that regulate NPC formation and dynamics, a novel fluorescence-based strategy was used. This approach is based on the functional tagging of NPC proteins with the green fluorescent protein (GFP), and the hypothesis that NPC assembly mutants will have distinct GFP-NPC signals as compared with wild-type (wt) cells. By fluorescence-activated cell sorting for cells with low GFP signal from a population of mutagenized cells expressing GFP-Nup49p, three complementation groups were identified: two correspond to mutant nup120 and gle2 alleles that result in clusters of NPCs. Interestingly, a third group was a novel temperature-sensitive allele of nup57. The lowered GFP-Nup49p incorporation in the nup57-E17 cells resulted in a decreased fluorescence level, which was due in part to a sharply diminished interaction between the carboxy-terminal truncated nup57p^E17 and wt Nup49p. Interestingly, the nup57-E17 mutant also affected the incorporation of a specific subset of other nucleoporins into the NPC. Decreased levels of NPC-associated Nsp1p and Nup116p were observed. In contrast, the localizations of Nic96p, Nup82p, Nup159p, Nup145p, and Pom152p were not markedly diminished. Coincidentally, nuclear import capacity was inhibited. Taken together, the identification of such mutants with specific perturbations of NPC structure validates this fluorescence-based strategy as a powerful approach for providing insight into the mechanism of NPC biogenesis.     

Cold-Sensitive Mutants of DROSOPHILA MELANOGASTER Defective in Ribosome Assembly

Thirteen X-linked, cold-sensitive lethal, female-sterile mutants of Drosophila melanogaster located at eight separate loci were screened for their ability to assemble ribosomes at the restrictive temperature of 17°. Females were labelled with ³H-uridine for either 2 or 20 hours at 17°. A mitochondria-free extract was prepared and analyzed by means of sucrose gradient centrifugation. Four of the mutants, l(1)TW-2 ^cs, l(1)HM16^cs, l(1)HM23^cs, and l(1)HM20 ^cs, had a lower ratio of cpm in the 40S subunit to cpm in the 60S subunit (40S:60S ratio) than wild type with a 2-hour label. The same was true of a 20-hour label of l(1)TW-2^cs, l(1)HM16^cs, and l(1)HM23^cs, which are allelic, resulted in a 40S:60S ratio higher than wild type. Four other cs mutants were found to have less drastic effects on ribosome assembly. The ribosomal subunits of mutants l(1)HM16^sc and l(1)HM20^cs sediment at the same rate as their wild-type counterparts. The same is true for the RNA in their ribosomal particles. Sucrose gradient analysis of ribosomes from cold-sensitive lethal, female-sterile mutants appears to be an effective method for finding mutants that affect ribosome assembly.     

Isolation and Characterization of Pep5, a Gene Essential for Vacuolar Biogenesis in Saccharomyces Cerevisiae

pep5 mutants of Saccharomyces cerevisiae accumulate inactive precursors to the vacuolar hydrolases. The PEP5 gene was isolated from a genomic DNA library by complementation of the pep5-8 mutation. Deletion analysis localized the complementing activity to a 3.3-kb DNA fragment. DNA sequence analysis of the PEP5 gene revealed an open reading frame of 1029 codons with a calculated molecular mass for the encoded protein of 117,403 D. Deletion/disruption of the PEP5 gene did not kill the cells. The resulting strains grow very slowly at 37 degrees. The disruption mutant showed greatly decreased activities of all vacuolar hydrolases examined, including PrA, PrB, CpY, and the repressible alkaline phosphatase. Apparently normal precursors forms of the proteases accumulated in pep5 mutants, as did novel forms of PrB antigen. Antibodies raised to a fusion protein that contained almost half of the PEP5 open reading frame allowed detection by immunoblot of a protein of relative molecular mass 107 kD in extracts prepared from wild-type cells. Cell fractionation showed the PEP5 gene product is enriched in the vacuolar fraction and appears to be a peripheral vacuolar membrane protein.     

Replication-Dependent Sister Chromatid Recombination in Rad1 Mutants of Saccharomyces Cerevisiae

Homolog recombination and unequal sister chromatid recombination were monitored in rad1-1/rad1-1 diploid yeast cells deficient for excision repair, and in control cells, RAD1/rad1-1, after exposure to UV irradiation. In a rad1-1/rad1-1 diploid, UV irradiation stimulated much more sister chromatid recombination relative to homolog recombination when cells were irradiated in the G(1) or the G(2) phases of the cell cycle than was observed in RAD1/rad1-1 cells. Since sister chromatids are not present during G(1), this result suggested that unexcised lesions can stimulate sister chromatid recombination events during or subsequent to DNA replication. The results of mating rescue experiments suggest that unexcised UV dimers do not stimulate sister chromatid recombination during the G(2) phase, but only when they are present during DNA replication. We propose that there are two types of sister chromatid recombination in yeast. In the first type, unexcised UV dimers and other bulky lesions induce sister chromatid recombination during DNA replication as a mechanism to bypass lesions obstructing the passage of DNA polymerase, and this type is analogous to the type of sister chromatid exchange commonly observed cytologically in mammalian cells. In the second type, strand scissions created by X-irradiation or the excision of damaged bases create recombinogenic sites that result in sister chromatid recombination directly in G(2). Further support for the existence of two types of sister chromatid recombination is the fact that events induced in rad1-1/rad1-1 were due almost entirely to gene conversion, whereas those in RAD1/rad1-1 cells were due to a mixture of gene conversion and reciprocal recombination.     

Saccharomyces Cerevisiae Null Mutants in Glucose Phosphorylation: Metabolism and Invertase Expression

A congenic series of Saccharomyces cerevisiae strains has been constructed which carry, in all combinations, null mutations in the three genes for glucose phosphorylation: HXK1, HXK2 and GLK1, coding hexokinase 1 (also called PI or A), hexokinase 2 (PII or B), and glucokinase, respectively: i.e., eight strains, all of which grow on glucose except for the triple mutant. All or several of the strains were characterized in their steady state batch growth with 0.2% or 2% glucose, in aerobic as well as respiration-inhibited conditions, with respect to growth rate, yield, and ethanol formation. Glucose flux values were generally similar for different strains and conditions, provided they contained either hexokinase 1 or hexokinase 2. And their aerobic growth, as known for wild type, was largely fermentative with ca. 1.5 mol ethanol made per mol glucose used. The strain lacking both hexokinases and containing glucokinase was an exception in having reduced flux, a result fitting with its maximal rate of glucose phosphorylation in vitro. Aerobic growth of even the latter strain was largely fermentative (ca. 1 mol ethanol per mol glucose). Invertase expression was determined for a variety of media. All strains with HXK2 showed repression in growth on glucose and the others did not. Derepression in the wild-type strain occurred at ca. 1 mM glucose. The metabolic data do not support- or disprove-a model with HXK2 having only a secondary role in catabolite repression related to more rapid metabolism.     

Altered Regulatory Responses to Glucose Are Associated with a Glucose Transport Defect in Grr1 Mutants of Saccharomyces Cerevisiae

The GRR1 gene of Saccharomyces cerevisiae affects glucose repression, cell morphology, divalent cation transport and other processes. We present a kinetic analysis showing that the grr1 mutant is also defective in high affinity glucose transport. In combination with a mutation in SNF3, a member of the glucose transporter gene family, grr1 strikingly impairs growth on glucose. These findings suggest that GRR1 and SNF3 affect glucose transport by distinct pathways. The mutation rgt1-1, a suppressor of snf3, restores both glucose transport and glucose repression to a grr1 mutant, but does not remedy the morphological defect. We suggest that GRR1 affects the glucose sensing process and that the association between transport and regulation may reflect the involvement of a transporter in glucose sensing.     

Isolation and Characterization of Mutants Which Show an Oversecretion Phenotype in Saccharomyces Cerevisiae

We have isolated mutants responsible for an oversecretion phenotype in Saccharomyces cerevisiae, using a promoter of SUC2 and the gene coding for alpha-amylase from mouse as a marker of secretion. These mutations defined two complementation groups, designated as ose1 (over secretion) and rgr1 (resistant to glucose repression). The ose1 mutant produced an oversecretion of amylase by 12- to 15-fold under derepressing conditions; however, the amylase mRNA was present at nearly the same amount as it was in the parent cells. No expression of the amylase gene was detected under repressing conditions. The rgr1 mutant oversecreted amylase by 11- to 13-fold under repressing conditions by 15- to 18-fold under derepressing conditions. The rgr1 mutant showed pleiotropic effects on the following cellular functions: (1) resistance to glucose repression, (2) temperature-sensitive lethality, (3) sporulation deficieny in homozygous diploid cells, and (4) abnormal cell morphology. The rgr1 mutation was not allelic with ssn6 and cyc9, and failed to suppress snf1.     

Trk2 Is Required for Low Affinity K(+) Transport in Saccharomyces Cerevisiae

TRK1, the gene encoding the high affinity K+ transporter in Saccharomyces cerevisiae, is nonessential due to the existence of a functionally independent low affinity transporter. To identify the gene(s) encoding the low affinity K+ transporter, we screened trk1 delta cells for mutants (Kla-) that require higher concentrations of K+ in the medium to support growth. trk1 delta trk2 mutants require up to tenfold higher concentrations of K+ to exhibit normal growth compared to trk1 delta TRK2 cells. K+ and 86Rb+ transport assays demonstrate that the mutant phenotype is due to defective K+ transport (uptake). Each of 38 independent mutants contains a mutation in the same gene, TRK2. Cells deficient for both high and low affinity K+ transport (trk1 delta trk2) exhibit hypersensitivity to low extracellular pH that can be suppressed by high concentrations of K+ but not Na+. TRK1 completely suppresses both the K+ transport defect and low pH hypersensitivity of trk2 cells, suggesting that TRK1 and TRK2 are functionally independent.     

Characterization of Synthetic-Lethal Mutants Reveals a Role for the Saccharomyces Cerevisiae Guanine-Nucleotide Exchange Factor Cdc24p in Vacuole Function and Na(+) Tolerance

Cdc24p is the guanine-nucleotide exchange factor for the Cdc42p GTPase, which controls cell polarity in Saccharomyces cerevisiae. To identify new genes that may affect cell polarity, we characterized six UV-induced csl (CDC24 synthetic-lethal) mutants that exhibited synthetic-lethality with cdc24-4(ts) at 23°. Five mutants were not complemented by plasmid-borne CDC42, RSR1, BUD5, BEM1, BEM2, BEM3 or CLA4 genes, which are known to play a role in cell polarity. The csl3 mutant displayed phenotypes similar to those observed with calcium-sensitive, Pet(-) vma mutants defective in vacuole function. CSL5 was allelic to VMA5, the vacuolar H(+)-ATPase subunit C, and one third of csl5 cdc24-4(ts) cells were elongated or had misshapen buds. A cdc24-4(ts) Δvma5::LEU2 double mutant did not exhibit synthetic lethality, suggesting that the csl5/vma5 cdc24-4(ts) synthetic-lethality was not simply due to altered vacuole function. The cdc24-4(ts) mutant, like Δvma5::LEU2 and csl3 mutants, was sensitive to high levels of Ca(2+) as well as Na(+) in the growth media, which did not appear to be a result of a fragile cell wall because the phenotypes were not remedied by 1 M sorbitol. Our results indicated that Cdc24p was required in one V-ATPase mutant and another mutant affecting vacuole morphology, and also implicated Cdc24p in Na(+) tolerance.     

Isolation of Saccharomyces cerevisiae Mutants Defective in Acyl Coenzyme A Synthetase

Mutants of Saccharomyces cerevisiae defective in acyl-CoA synthetase (EC 6.2.1.3) were isolated. The mutants were concentrated by the radiation-suicide technique with the use of tritiated palmitic acid. Selection of the mutants was based on the premise that acyl-CoA synthetase activity would become indispensable when yeast cells in which fatty acid synthesis de novo is blocked are grown in a medium supplemented with fatty acid. The mutant strains isolated exhibited low acyl-CoA synthetase activity in vitro. Furthermore, they accumulated markedly more of the incorporated palmitic acid in the nonesterified form than did the wild- type strain. Some of the mutants showed thermosensitive acyl-CoA synthetase activity, indicating a mutation of the structural gene of the enzyme. Genetic studies on these mutants indicated that their phenotype resulted from a single, recessive mutation of a nuclear gene, designated faa 1 (fatty acid activation).