Molecular Basis of Fructose Utilization by the Wine Yeast Saccharomyces cerevisiae: a Mutated HXT3 Allele Enhances Fructose Fermentation

Fructose utilization by wine yeasts is critically important for the maintenance of a high fermentation rate at the end of alcoholic fermentation. A Saccharomyces cerevisiae wine yeast able to ferment grape must sugars to dryness was found to have a high fructose utilization capacity. We investigated the molecular basis of this enhanced fructose utilization capacity by studying the properties of several hexose transporter (HXT) genes. We found that this wine yeast harbored a mutated HXT3 allele. A functional analysis of this mutated allele was performed by examining expression in an hxt1-7Δ strain. Expression of the mutated allele alone was found to be sufficient for producing an increase in fructose utilization during fermentation similar to that observed in the commercial wine yeast. This work provides the first demonstration that the pattern of fructose utilization during wine fermentation can be altered by expression of a mutated hexose transporter in a wine yeast. We also found that the glycolytic flux could be increased by overexpression of the mutant transporter gene, with no effect on fructose utilization. Our data demonstrate that the Hxt3 hexose transporter plays a key role in determining the glucose/fructose utilization ratio during fermentation.     

Cloning of an Arabidopsis thaliana cDNA coding for farnesyl diphosphate synthase by functional complementation in yeast

A cDNA encoding farnesyl diphosphate synthase, an enzyme that synthesizes C15 isoprenoid diphosphate from isopentenyl diphosphate and dimethylallyl diphosphate, was cloned from an Arabidopsis thaliana cDNA library by complementation of a mutant of Saccharomyces cerevisiae deficient in this enzyme. The A. thaliana cDNA was also able to complement the lethal phenotype of the erg20 deletion yeast mutant. As deduced from the full-length 1.22 kb cDNA nucleotide sequence, the polypeptide contains 343 amino acids and has a relative molecular mass of 39689. The predicted amino acid sequence presents about 50% identity with the yeast, rat and human FPP synthases. Southern blot analyses indicate that A. thaliana probably contains a single gene for farnesyl diphosphate synthase.     

Construction of a flocculent Saccharomyces cerevisiae fermenting lactose

A flocculent Saccharomyces cerevisiae strain with the ability to express both the LAC4 (coding for β-galactosidase) and LAC12 (coding for lactose permease) genes of Kluyveromyces marxianus was constructed. This recombinant strain is not only able to grow on lactose, but it can also ferment this substrate. To our knowledge this is the first time that a recombinant S. cervisiae has been found to ferment lactose in a way comparable to that of the existing lactose-fermenting yeast strains. Moreover, the flocculating capacity of the strain used in this work gives the process several advantages. On the one hand, it allows for operation in a continuous mode at high cell concentration, thus increasing the system's overall productivity; on the other hand, the biomass concentration in the effluent is reduced, thus decreasing product separation/purification costs. Received: 2 October 1998 / Received revision: 15 January 1999 / Accepted: 17 January 1999     

Avoiding entry into intracellular protein degradation pathways by signal mutations increases protein secretion in Pichia pastoris

In our previous study, we serendipitously discovered that protein secretion in the methylotrophic yeast Pichia pastoris is enhanced by a mutation (V50A) in the mating factor alpha (MFα) prepro-leader signal derived from Saccharomyces cerevisiae. In the present study, we investigated 20 single-amino-acid substitutions, including V50A, located within the MFα signal peptide, indicating that V50A and several single mutations alone provided significant increase in production of the secreted proteins. In addition to hydrophobicity index analysis, both an unfolded protein response (UPR) biosensor analysis and a microscopic observation showed a clear difference on the levels of UPR induction and mis-sorting of secretory protein into vacuoles among the wild-type and mutated MFα signal peptides. This work demonstrates the importance of avoiding entry of secretory proteins into the intracellular protein degradation pathways, an observation that is expected to contribute to the engineering of strains with increased production of recombinant secreted proteins.     

Mutation at the CK2 phosphorylation site on Cdc28 affects kinase activity and cell size in Saccharomyces cerevisiae

We have recently reported that protein kinase CK2 phosphortylates both in vivo and in vitro residue serine-46 of the cell cycle regulating protein Cdc28 of budding yeast Saccharomyces cerevisiae, confirming a previous observation that the same site is phosphorylated in Cdc2/Cdk1, the human homolog of Cdc28. In addition, S. cerevisiae in which serine-46 of Cdc28 has been mutated to alanine show a decrease of 33% in both cell volume and protein content, providing the genetic evidence that CK2 is involved in the regulation of budding yeast cell division cycle, and suggesting that this regulation may be brought about in G1 phase of the mammalian cell cycle. Here, we extended this observation reporting that the mutation of serine-46 of Cdc28 to glutamic acid doubles, at least in vitro, the H1-kinase activity of the Cdc28/cyclin A complex. Since this mutation has only little effects on the cell size of the cells, we hypothesize multiple roles of yeast CK2 in regulating the G1 transition in budding yeast.     

A new method for isolation of S-adenosylmethionine (SAM)-accumulating yeast

S-Adenosylmethionine (SAM) is an important metabolite that participates in many reactions as a methyl group donor in all organisms, and has attracted much interest in clinical research because of its potential to improve many diseases, such as depression, liver disease, and osteoarthritis. Because of these potential applications, a more efficient means is needed to produce SAM. Accordingly, we developed a positive selection method to isolate SAM-accumulating yeast in this study. In Saccharomyces cerevisiae, one of the main reactions consuming SAM is thought to be the methylation reaction in the biosynthesis of ergosterol that is catalyzed by Erg6p. Mutants with deficiencies in ergosterol biosynthesis may accumulate SAM as a result of the reduction of SAM consumption in ergosterol biosynthesis. We have applied this method to isolate SAM-accumulating yeasts with nystatin, which has been used to select mutants with deficiencies in ergosterol biosynthesis. SAM-accumulating mutants from S. cerevisiae K-9 and X2180-1A were efficiently isolated through this method. These mutants accumulated 1.7–5.5 times more SAM than their parental strains. NMR and GC-MS analyses suggested that two mutants from K-9 have a mutation in the erg4 gene, and erg4 disruptants from laboratory strains also accumulated more SAM than their parental strains. These results indicate that mutants having mutations in the genes for enzymes that act downstream of Erg6p in ergosterol biosynthesis are effective in accumulating SAM.     

The Saccharomyces cerevisiae mevalonate diphosphate decarboxylase is essential for viability, and a single Leu-to-Pro mutation in a conserved sequence leads to thermosensitivity.

The mevalonate diphosphate decarboxylase is an enzyme which converts mevalonate diphosphate to isopentenyl diphosphate, the building block of isoprenoids. We used the Saccharomyces cerevisiae temperature-sensitive mutant defective for mevalonate diphosphate decarboxylase previously described (C. Chambon, V. Ladeveve, M. Servouse, L. Blanchard, C. Javelot, B. Vladescu, and F. Karst, Lipids 26:633-636, 1991) to characterize the mutated allele. We showed that a single change in a conserved amino acid accounts for the temperature-sensitive phenotype of the mutant. Complementation experiments were done both in the erg19-mutated background and in a strain in which the ERG19 gene, which was shown to be an essential gene for yeast, was disrupted. Epitope tagging of the wild-type mevalonate diphosphate decarboxylase allowed us to isolate the enzyme in an active form by a versatile one-step immunoprecipitation procedure. Furthermore, during the course of this study, we observed that a high level of expression of the wild-type ERG19 gene led to a lower sterol steady-state accumulation compared to that of a wild-type strain, suggesting that this enzyme may be a key enzyme in mevalonate pathway regulation.     

A dominant interfering mutation in RAS1 of Saccharomyces cerevisiae

A mutant allele of RAS1 that dominantly interferes with the wild-type Ras function in the yeast Saccharomyces cerevisiae was discovered during screening of mutants that suppress an ira2 disruption mutation. A single amino acid substitution, serine for glycine at position 22, was found to cause the mutant phenotype. The inhibitory effect of the RAS1 ^Ser22 gene could be overcome either by overexpression of CDC25 or by the ira2 disruption mutation. These results suggest that the RAS1^Ser22 gene product interferes with the normal interaction of Ras with Cdc25 by forming a dead-end complex between Ras1^Ser22 and Cdc25 proteins.     

A missense mutation in the nuclear gene coding for the mitochondrial aspartyl-tRNA synthetase suppresses a mitochondrial tRNA(Asp) mutation

The nuclear suppressor allele NSM3 in strain FF1210-6C/170-E22 (E22), which suppresses a mutation of the yeast mitochondrial tRNA^Asp gene in Saccharomyces cerevisiae, was cloned and identified. To isolate the NSM3 allele, a genomic DNA library using the vector YEp13 was constructed from strain E22. Nine YEp13 recombinant plasmids were isolated and shown to suppress the mutation in the mitochondrial tRNA^Asp gene. These nine plasmids carry a common 4.5-kb chromosomal DNA fragment which contains an open reading frame coding for yeast mitochondrial aspartyl-tRNA synthetase (AspRS) on the basis of its sequence identity to the MSD1 gene. The comparison of NSM3 DNA sequences between the suppressor and the wild-type version, cloned from the parental strain FF1210-6C/170, revealed a G to A transition that causes the replacement of amino acid serine (AGU) by an asparagine (AAU) at position 388. In experiments switching restriction fragments between the wild type and suppressor versions of the NSM3 gene, the rescue of respiratory deficiency was demonstrated only when the substitution was present in the construct. We conclude that the base substitution causes the respiratory rescue and discuss the possible mechanism as one which enhances interaction between the mutated tRNA^Asp and the suppressor version of AspRS.     

Expression of 15N-labeled eukaryotic cytochrome c in Escherichia coli

 We present a simple and inexpensive method for producing ¹⁵N-labeled Saccharomyces cerevisiae iso-1-cytochrome c in Escherichia coli. The labeled protein gives excellent NMR spectra. Received: 18 December 1998 / Accepted: 27 January 1999     

The identification of a Caenorhabditis elegans homolog of p34cdc2 kinase

We have identified a Caenorhabditis elegans homolog of p34^cdc2 kinase. The C. elegans homolog, ncc-1, is -60% identical to p34^cdc2 of Homo sapiens. When expressed from a constitutive yeast promoter, ncc-1 is capable of complementing a conditional lethal mutation in the CDC28 gene of Saccharomyces cerevisiae, indicating that this C. elegans homolog can properly regulate the cell cycle.     

URA3基因影响青蒿酸酿酒酵母工程菌中试发酵产量

CRISPR/Cas9基因编辑技术已经被广泛应用于工程酿酒酵母的基因插入、基因替换和基因敲除,通过使用选择标记进行基因编辑具有简单高效的特点。前期利用CRISPR/Cas9系统敲除青蒿酸生产菌株酿酒酵母(Saccharomyces cerevisiae) 1211半乳糖代谢负调控基因GAL80,获得菌株S. cerevisiae 1211-2,在不添加半乳糖诱导的情况下,青蒿酸摇瓶发酵产量达到了740 mg/L。但在50 L中试发酵实验中,S. cerevisiae 1211-2很难利用对青蒿酸积累起到决定性作用的碳源-乙醇,青蒿酸的产量仅为亲本菌株S.cerevisiae 1211的20%–25%。我们推测因遗传操作所需的筛选标记URA3突变,影响了其生长及青蒿酸产量。随后我们使用重组质粒pML104-KanMx4-u连同90 bp供体DNA成功恢复了URA3基因,获得了工程菌株S. cerevisiae 1211-3。S. cerevisiae 1211-3能够在葡萄糖和乙醇分批补料的发酵罐中正常生长,其青蒿酸产量超过20g/L,与亲本菌株产量相当。研究不但获得了不加半乳糖诱导的青...     

Genetic evidence for interaction between components of the yeast 26S proteasome: combination of a mutation in RPN12 (a lid component gene) with mutations in RPT1 (an ATPase gene) causes synthetic lethality

The 19S regulatory particle of the yeast 26S proteasome consists of six related ATPases (Rpt proteins) and at least 11 non-ATPase proteins (Rpn proteins). RPN12 (formerly NIN1) encodes an Rpn component of the 19S regulatory particle and is essential for growth. To determine which subunit(s) of the 26S proteasome interact(s) with Rpn12, we attempted to screen for mutations that cause synthetic lethality in the presence of the rpn12-1 (formerly nin1-1) mutation. Among the candidates recovered was a new allele of RPT1 (formerly CIM5). This mutant allele was designated rpt1-2; on its own this mutation caused no phenotypic change, whereas the rpn12-1 rpt1-2 double mutant was lethal, suggesting a strong interaction between Rpn12 and Rpt1. The site of the rpt1-2 mutation was determined by DNA sequencing of the RPT1 locus retrieved from the mutant, and a single nucleotide alteration was found. This changes amino acid 446 of the RPT1 product from alanine to valine. The alanine residue is conserved in all Rpt proteins, except Rpt5, but no function has yet been assigned to the region that contains it. We propose that this region is necessary for Rpt1 to interact with Rpn12. The terminal phenotype of the rpn12-1 rpt1-2 double mutant was not cell cycle specific, suggesting that in the double mutant cells the function of the 26S proteasome is completely eliminated, thereby inducing multiple defects in cellular functions. Received: 1 February 1999 / Accepted: 5 May 1999     

Induction of forward mutations in mutationally defective yeast

Summary The 3 rev loci that reduce ultraviolet light (UV)-induced reversion in S. cerevisiae had a similar effect on forward mutation to auxotrophy induced by a single 400 erg/mm² UV dose: rev1-1, rev2-1 and rev3-1 reduced average frequencies of auxotrophs to 4%, 64% and 4% that in wild type and reduced frequencies of mutants at ade1 or ade2 to 19%, 88% and 2% wild type, respectively. The rev2-1 strain exhibited high frequencies of spontaneous mutation. It is suggested that rev1-1 and rev3-1 block steps in a general UV mutation mechanism controlling forward and reverse mutation throughout the genome. The small effect of rev2-1, compared to the effect of rev1-1 or rev3-1, is consistent with previously obtained data on UV reversion and could be due to a specificity for induced mutation involving only certain types of UV damage or, on the other hand, it may be related to mutator activity. Although rev caused varying degrees of sensitivity to ethylmethanesulfonate (EMS), there was little or no significant effect on mutation induced by a single 30 min. dose of 3% EMS. Auxotroph frequencies were 79%, 109% and 94% wild type, whild frequencies at ade1 or ade2 were 82%, 56% and 51% wild type in the respective strains. It is suggested that steps blocked by rev, although they may participate in repair of lethal EMS damage, do not themselves generate EMS-induced mutations.     

The isolation and characterization of ngm2, a mutation that affects nitrosoguanidine mutagenesis in yeast

Summary We have isolated and characterized a new mutant of Saccharomyces cerevisiae, carrying a single mutant allele that we designate ngm2-1, which is defective with respect to induced mutagenesis. This mutant was isolated by screening mutagenized clones for reduced frequencies of reversion of the his1-7 allele, induced by N-methyl-N-nitro-N-nitrosoguanidine. As judged by the reversion of his1-7 and ilv1-92, ngm2-1 mutant strains are also deficient with respect to mutability induced by methyl methane sulfonate, ethyl methane sulfonate and, at least partially, by UV. UV-induced reversion of the ochre mutation arg4-17 and the frameshift mutation his4-38 was not much affected by ngm2-1, however. Like rev3 and rev7 mutations, ngm2-1 also has little influence on the reversion of the proline missense allele, cyc1-115. Ngm2-1 mutants are only at best very slightly more sensitive to the toxicity of the four mutagens used, and homozygous diploids sporulate normally.     

Simulation of structural and functional properties of mevalonate diphosphate decarboxylase (MVD)

Mevalonate 5-diphosphate decarboxylase (MVD) is an important enzyme in the mevalonate pathway catalyzing the ATP-dependent decarboxylation of mevalonate 5-diphosphate (MDP) to yield isopentynyl diphosphate (IPP) which is an ubiquitous precursor for isoprenoids and sterols. Although there are studies to show the involvement of certain amino acid residues in MVD activity, the structure and the function of the active site is yet to be investigated. Therefore the objectives of this study were to elucidate the active site of Saccharomyces cerevisiae MVD (scMVD) using a molecular docking and simulation-based approach. The Cartesian coordinates of scMVD retrieved from the PDB database were used in the docking procedure. 3D atomic coordinates of MDP, ATP and an inhibitor trifluoromevalonate (TFMDP) were generated using Gaussian 98. ATP, MDP and TFMDP were docked into the potential active site identified by sequence analyses using Hex 4.2. The complexes obtained from docking procedure were subjected to 1.5 ns simulation by GROMACS 3.2. Investigation of complexes revealed that Ala15, Lys18, Ser121 &; Ser155; Lys22, Ser153 &; Ser155 and Tyr19, Ser121, Ser153, Gly154 &; Thr209 of MVD are within hydrogen bond forming distances of MDP, ATP and TFMDP, respectively indicating their possible involvement in active site formation through H-bond formation. The presence of a water molecule between the carboxyl group of Asp302, a previously characterized active site residue and C3 region of MDP at a distance of 3 Å suggests that deprotonation of the hydroxyl of the C3 takes place via a water molecule. Conjunction with reported crucial catalytic activity of Ser121 of MVD and our finding of the presence of this residue in hydrogen bond forming distance to MDP suggests that this hydrogen bond helps in proper orienting of MDP for phosphorylation /decarboxylation. We further suggest that the reported greater RMS deviation of Pro₇₉- Leu mutated MVD with respect to native MVD of temperature sensitive mutant phenotype of S. cerevisiae is due to partial unfolding of MVD as a result of mutation. Finally, this study provides a tantalizing glimpse about hitherto unknown structural and functional properties of the active site of MVD.     

Genetic interaction of DED1 encoding a putative ATP-dependent RNA helicase with SRM1 encoding a mammalian RCC1 homolog in Saccharomyces cerevisiae

 The Saccharomyces cerevisiae temperature-sensitive mutants srm1-1, mtr1-2 and prp20-1 carry alleles of a gene encoding a homolog of mammalian RCC1. In order to identify a protein interacting with RCC1, a series of suppressors of the srm1-1 mutation were isolated as cold-sensitive mutants and one of the mutants, designated ded1-21, was found to be defective in the DED1 gene. The double mutant, srm1-1 ded1-21, could grow at 35° C, but not at 37° C. A revertant of srm1-1 ded1-21 that became able to grow at 37° C acquired another mutation in the SRM1 gene, indicating the tight relationship between SRM1 and DED1. In all the rcc1 ^- strains examined, the amount of mutated SRM1 proteins was reduced or not detectable at the nonpermissive temperature. While mutated SRM1 protein was stabilized in all of the rcc1 ^- strains by the ded1-21 mutation, the ded1-21 mutation suppressed both srm1-1 and mtr1-2, but not the prp20-1 mutation, contrary to the previous finding that overproduction of the S. cerevisiae Ran homolog GSP1 suppresses prp20-1, but not srm1-1 or mtr1-2. Received: 20 March 1996/Accepted: 1 July 1996     

Analysis of yeast pms1, msh2, and mlh1 mutators points to differences in mismatch correction efficiencies between prokaryotic and eukaryotic cells.

Genetic stability relies in part on the efficiency with which post-replicative mismatch repair (MMR) detects and corrects DNA replication errors. In Escherichia coli, endogenous transition mispairs and insertion/deletion (ID) heterologies are corrected with similar efficiencies – but much more efficiently than transversion mispairs – as revealed by mutation rate increases in MMR mutants. To assess the relative efficiencies with which these mismatches are corrected in the yeast Saccharomyces cerevisiae, we examined repair of defined mismatches on heteroduplex plasmids and compared the spectra for >1000 spontaneous SUP4-o mutations arising in isogenic wild-type or MMR-deficient (pms1, mlh1, msh2) strains. Heteroduplexes containing G/T mispairs or ID heterologies were corrected more efficiently than those containing transversion mismatches. However, the rates of single base-pair insertion/deletion were increased much more (82-fold or 34-fold, respectively) on average than the rate of base pair substitutions (4.4-fold), with the rates for total transitions and transversions increasing to similar extents. Thus, the relative efficiencies with which mismatches formed during DNA replication are repaired appear to differ in prokaryotic and eukaryotic cells. In addition, our results indicate that in yeast, and probably other eukaryotes, these efficiencies may not mirror those obtained from an analysis of heteroduplex correction. Received: 15 November 1998 / Accepted: 4 February 1999     

Production of the Artemisinin Precursor Amorpha-4,11-diene by Engineered Saccharomyces cerevisiae

The gene encoding for amorpha-4,11-diene synthase from Artemisia annua was transformed into yeast Saccharomyces cerevisiae in two fundamentally different ways. First, the gene was subcloned into the galactose-inducible, high-copy number yeast expression vector pYeDP60 and used to transform the Saccharomyces cerevisiae strain CEN·PK113-5D. Secondly, amorpha-4,11-diene synthase gene, regulated by the same promoter, was introduced into the yeast genome by homologous recombination. In protein extracts from galactose-induced yeast cells, a higher activity was observed for yeast expressing the enzyme from the plasmid. The genome-transformed yeast grows at the same rate as wild-type yeast while plasmid-carrying yeast grows somewhat slower than the wild-type yeast. The plasmid and genome-transformed yeasts produced 600 and 100 μg/l of the artemisinin precursor amorpha-4,11-diene, respectively, during 16-days’ batch cultivation. Revisions requested 14 November 2005; Revisions received 17 January 2006