Saccharomyces Cerevisiae Sc Research Articles

Improving 2-phenylethanol production via Ehrlich pathway using genetic engineered Saccharomyces cerevisiae strains.

2-phenylethanol (2-PE) is an important aromatic compound with a rose-like fragrance widely used in food industry and cosmetic manufacture. In order to obtain "natural" 2-PE, the genetically modified budding yeasts were developed and applied for the 2-PE production. The gene ARO8 encoding transaminase and the gene ARO10 encoding decarboxylase in the Ehrlich pathway were expressed in Saccharomyces cerevisiae S288c. The activities of transaminase and decarboxylase were both enhanced in the corresponding recombinant strains. Consequently, the 2-PE yield in the recombinant strains with ARO8 and ARO10 were increased by 9.3 and 16.3 %, respectively, than that in the wild strain. A co-expression vector harboring ARO8 and ARO10 was then introduced into S. cerevisiae S288c, generating the recombinant strain SPO810. The fed-batch fermentation results indicated that the 2-PE yield in SPO810 reached 2.61 g L(-1) after 60 h of cultivation, which was 36.8 % higher than that in the wild strain. These results demonstrated that the 2-PE production was significantly improved by enhanced expression of the two key enzymes encoded by ARO8 and ARO10 in the Ehrlich pathway, providing new perspectives for enhancing "natural" 2-PE production in S. cerevisiae.

Software for pre-processing Illumina next-generation sequencing short read sequences.

BackgroundWhen compared to Sanger sequencing technology, next-generation sequencing (NGS) technologies are hindered by shorter sequence read length, higher base-call error rate, non-uniform coverage, and platform-specific sequencing artifacts. These characteristics lower the quality of their downstream analyses, e.g. de novo and reference-based assembly, by introducing sequencing artifacts and errors that may contribute to incorrect interpretation of data. Although many tools have been developed for quality control and pre-processing of NGS data, none of them provide flexible and comprehensive trimming options in conjunction with parallel processing to expedite pre-processing of large NGS datasets.MethodsWe developed ngsShoRT (next-generation sequencing Short Reads Trimmer), a flexible and comprehensive open-source software package written in Perl that provides a set of algorithms commonly used for pre-processing NGS short read sequences. We compared the features and performance of ngsShoRT with existing tools: CutAdapt, NGS QC Toolkit and Trimmomatic. We also compared the effects of using pre-processed short read sequences generated by different algorithms on de novo and reference-based assembly for three different genomes: Caenorhabditis elegans, Saccharomyces cerevisiae S288c, and Escherichia coli O157 H7.ResultsSeveral combinations of ngsShoRT algorithms were tested on publicly available Illumina GA II, HiSeq 2000, and MiSeq eukaryotic and bacteria genomic short read sequences with the focus on removing sequencing artifacts and low-quality reads and/or bases. Our results show that across three organisms and three sequencing platforms, trimming improved the mean quality scores of trimmed sequences. Using trimmed sequences for de novo and reference-based assembly improved assembly quality as well as assembler performance. In general, ngsShoRT outperformed comparable trimming tools in terms of trimming speed and improvement of de novo and reference-based assembly as measured by assembly contiguity and correctness.ConclusionsTrimming of short read sequences can improve the quality of de novo and reference-based assembly and assembler performance. The parallel processing capability of ngsShoRT reduces trimming time and improves the memory efficiency when dealing with large datasets. We recommend combining sequencing artifacts removal, and quality score based read filtering and base trimming as the most consistent method for improving sequence quality and downstream assemblies.ngsShoRT source code, user guide and tutorial are available at http://research.bioinformatics.udel.edu/genomics/ngsShoRT/. ngsShoRT can be incorporated as a pre-processing step in genome and transcriptome assembly projects.

Biochemical and Structural Analysis of RraA Proteins To Decipher Their Relationships with 4-Hydroxy-4-methyl-2-oxoglutarate/4-Carboxy-4-hydroxy-2-oxoadipate Aldolases

4-Hydroxy-4-methyl-2-oxoglutarate (HMG)/4-carboxy-4-hydroxy-2-oxoadipate (CHA) aldolases are class II (divalent metal ion dependent) pyruvate aldolases from the meta cleavage pathways of protocatechuate and gallate. The enzyme from Pseudomonas putida F1 is structurally similar to a group of proteins termed regulators of RNase E activity A (RraA) that bind to the regulatory domain of RNase E and inhibit the ribonuclease activity in certain bacteria. Analysis of homologous RraA-like proteins from varying species revealed that they share sequence conservation within the active site of HMG/CHA aldolase. In particular, the P. putida F1 HMG/CHA aldolase has a D-X20-R-D motif, whereas a G-X20-R-D-X2-E/D motif is observed in the structures of the RraA-like proteins from Thermus thermophilus HB8 (TtRraA) and Saccharomyces cerevisiae S288C (Yer010Cp) that may support metal binding. TtRraA and Yer010Cp were found to contain HMG aldolase and oxaloacetate decarboxylase activities. Similar to the P. putida F1 HMG/CHA aldolase, both TtRraA and Yer010Cp enzymes required divalent metal ions for activity and were competitively inhibited by oxalate, a pyruvate enolate analogue, suggesting a common mechanism among the enzymes. The RraA from Escherichia coli (EcRraA) lacked detectable C-C lyase activity. Upon restoration of the G-X20-R-D-X2-E/D motif, by site-specific mutagenesis, the EcRraA variant was able to catalyze oxaloacetate decarboxylation. Sequence analysis of RraA-like gene products found across all the domains of life revealed conservation of the metal binding motifs that can likely support a divalent metal ion-dependent enzyme reaction either in addition to or in place of the putative RraA function.

Next-generation sequencing of Okazaki fragments extracted from Saccharomyces cerevisiae

Genome-wide Okazaki fragment distribution can differentiate the discontinuous from the semi-discontinuous DNA replication model. Here, we investigated the genome-wide Okazaki fragment distribution in Saccharomyces cerevisiae S288C. We improved the method based upon lambda exonuclease digestion to purify Okazaki fragments from S288C yeast cells, followed by Illumina sequencing. The distribution of Okazaki fragments around confirmed replication origins, including two highly efficient replication origins, supported the discontinuous DNA replication model. In S. cerevisiae mitochondria, Okazaki fragments were overrepresented in the transcribed regions, indicating the interplay between transcription and DNA replication.

Version 6 of the consensus yeast metabolic network refines biochemical coverage and improves model performance.

Updates to maintain a state-of-the art reconstruction of the yeast metabolic network are essential to reflect our understanding of yeast metabolism and functional organization, to eliminate any inaccuracies identified in earlier iterations, to improve predictive accuracy and to continue to expand into novel subsystems to extend the comprehensiveness of the model. Here, we present version 6 of the consensus yeast metabolic network (Yeast 6) as an update to the community effort to computationally reconstruct the genome-scale metabolic network of Saccharomyces cerevisiae S288c. Yeast 6 comprises 1458 metabolites participating in 1888 reactions, which are annotated with 900 yeast genes encoding the catalyzing enzymes. Compared with Yeast 5, Yeast 6 demonstrates improved sensitivity, specificity and positive and negative predictive values for predicting gene essentiality in glucose-limited aerobic conditions when analyzed with flux balance analysis. Additionally, Yeast 6 improves the accuracy of predicting the likelihood that a mutation will cause auxotrophy. The network reconstruction is available as a Systems Biology Markup Language (SBML) file enriched with Minimium Information Requested in the Annotation of Biochemical Models (MIRIAM)-compliant annotations. Small- and macromolecules in the network are referenced to authoritative databases such as Uniprot or ChEBI. Molecules and reactions are also annotated with appropriate publications that contain supporting evidence. Yeast 6 is freely available at http://yeast.sf.net/ as three separate SBML files: a model using the SBML level 3 Flux Balance Constraint package, a model compatible with the MATLAB® COBRA Toolbox for backward compatibility and a reconstruction containing only reactions for which there is experimental evidence (without the non-biological reactions necessary for simulating growth).Database URL: http://yeast.sf.net/

Molecular genetic differentiation of yeast α-glucosidases: Maltase and isomaltase

The review is dedicated to the molecular genetics of yeast α-glucosidases: the maltase and isomaltase isozymes. Comparative analysis of the genome sequence of the yeast Saccharomyces cerevisiae S288C using the isomaltase gene of Saccharomyces cerevisiae ATCC56960 revealed a new family of polymeric isomaltase genes IMA1-IMA5 located in the telomeric regions of chromosomes VII, XV, IX, X, and X, respectively. The isomaltase overexpression and substrate specificity are discussed.

English

Fermentation products are indigenous to many civilizations, and they have been produced by industries since a long time. Saccharomyces cerevisiae S288C (commonly known as baker's yeast) is the strain mainly used in the Glucose based fermentation industries. We have seen the use of same yeast strain at different places with different Phenotypic Constraints. The way to improve the adaptability of considered strain for desired phenotypic conditions, using smart selection of genes through cybernetic modeling is illustrated. Phylogenetic homologues for all S. cerevisiae S288c Glucose Fermentation pathway genes were screened to search evolutionarily related functional domains in other yeast strains like Saccharomyces cerevisiae YJM789, Candida glabrata CBS138, Kluyveromyces lactis NRRL Y-1140, Ashbya gossypii ATCC10895 etc., which are adapted naturally in different set of environment. We observed that Saccharomyces cerevisiae YJM789, Candida glabrata CBS138, Ashbya gossypii ATCC10895, Kluyveromyces lactis NRRL Y-1140 possess highly conserved functional domains, which can be carefully selected based on usage. This study aims at designing an algorithm to select and incorporate evolutionary homologues for genes of a considered strain, which mostly show sub-optimal performance in the desired set of experimental constraints. Such a consideration of native microenvironment and evolutionary closeness in the selection of functional homologues of the entire genetic set can thus be significantly fruitful.

PSK2 coordinates glucose metabolism and utilization to maintain Ultradian clock-coupled respiratory oscillation in Saccharomyces cerevisiae yeast

Ultradian clock-coupled respiratory oscillation (UCRO) in an aerobic continuous culture of Saccharomyces cerevisiae S288C is principally regulated by control of certain redox reactions of energy metabolism. It is also modulated by the metabolism of storage carbohydrates during adaptation to environmental change. However, the mechanism of cell sensing and response to environmental nutrients in UCRO is unknown. The purpose of the present study was to determine the role of PSK2 kinase in UCRO in yeast. S. cerevisiae in culture showed oscillation in PSK2 mRNA levels with a definite phase relationship to the respiratory oscillation. Furthermore, inactivation of Psk2 by gene disruption severely affected UCRO and its decline to undetectable levels within 2days. In addition, the extracellular and intracellular glucose concentrations of PSK2 deletion mutants in culture were higher and lower, respectively, than those of the wild type. PSK2 mutant cells showed no alteration in redox state. Furthermore, the levels of storage carbohydrates such as glycogen and trehalose fluctuated in PSK2 mutants with attenuated amplitudes comparable to those in the wild type. The results indicated that PSK2 kinase is important for the uptake of glucose and regulation of storage-carbohydrate synthesis and hence the maintenance of an unperturbed continuously oscillating state.

Measuring and detecting molecular adaptation in codon usage against nonsense errors during protein translation.

Codon usage bias (CUB) has been documented across a wide range of taxa and is the subject of numerous studies. While most explanations of CUB invoke some type of natural selection, most measures of CUB adaptation are heuristically defined. In contrast, we present a novel and mechanistic method for defining and contextualizing CUB adaptation to reduce the cost of nonsense errors during protein translation. Using a model of protein translation, we develop a general approach for measuring the protein production cost in the face of nonsense errors of a given allele as well as the mean and variance of these costs across its coding synonyms. We then use these results to define the nonsense error adaptation index (NAI) of the allele or a contiguous subset thereof. Conceptually, the NAI value of an allele is a relative measure of its elevation on a specific and well-defined adaptive landscape. To illustrate its utility, we calculate NAI values for the entire coding sequence and across a set of nonoverlapping windows for each gene in the Saccharomyces cerevisiae S288c genome. Our results provide clear evidence of adaptation to reduce the cost of nonsense errors and increasing adaptation with codon position and expression. The magnitude and nature of this adaptation are also largely consistent with simulation results in which nonsense errors are the only selective force driving CUB evolution. Because NAI is derived from mechanistic models, it is both easier to interpret and more amenable to future refinement than other commonly used measures of codon bias. Further, our approach can also be used as a starting point for developing other mechanistically derived measures of adaptation such as for translational accuracy.

The Vam6 GEF Controls TORC1 by Activating the EGO Complex

The target of rapamycin complex 1 (TORC1) is a central regulator of eukaryotic cell growth that is activated by a variety of hormones (e.g., insulin) and nutrients (e.g., amino acids) and is deregulated in various cancers. Here, we report that the yeast Rag GTPase homolog Gtr1, a component of the vacuolar-membrane-associated EGO complex (EGOC), interacts with and activates TORC1 in an amino-acid-sensitive manner. Expression of a constitutively active (GTP-bound) Gtr1(GTP), which interacted strongly with TORC1, rendered TORC1 partially resistant to leucine deprivation, whereas expression of a growth inhibitory, GDP-bound Gtr1(GDP), caused constitutively low TORC1 activity. We also show that the nucleotide-binding status of Gtr1 is regulated by the conserved guanine nucleotide exchange factor (GEF) Vam6. Thus, in addition to its regulatory role in homotypic vacuolar fusion and vacuole protein sorting within the HOPS complex, Vam6 also controls TORC1 function by activating the Gtr1 subunit of the EGO complex.

Growth characteristics of Saccharomyces cerevisiae S288C in changing environmental conditions: auxo-accelerostat study

The effect of individual environmental conditions (pH, pO(2), temperature, salinity, concentration of ethanol, propanol, tryptone and yeast extract) on the specific growth rate as well as ethanol and glycerol production rate of Saccharomyces cerevisiae S288C was mapped during the fermentative growth in aerobic auxo-accelerostat cultures. The obtained steady-state values of the glycerol to ethanol formation ratio (0.1 mol mol(-1)) corresponding to those predicted from the stoichiometric model of fermentative yeast growth showed that the complete repression of respiration was obtained in auxostat culture and that the model is suitable for calculation of Y(ATP) and Q(ATP) values for the aerobic fermentative growth. Smooth decrease in the culture pH and dissolved oxygen concentration (pO2) down to the critical values of 2.3 and 0.8%, respectively, resulted in decrease in growth yield (Y(ATP)) and specific growth rate, however the specific ATP production rate (Q(ATP)) stayed almost constant. Increase in the concentration of biomass (>0.8 g dwt l(-1)), propanol (>2 g l(-1)) or NaCl (>15 g l(-1)) lead at first to the decrease in the specific growth rate and Q(ATP), while Y(ATP) was affected only at higher concentrations. The observed decrease in Q(ATP) was caused by indirect rather than direct inhibition of glycolysis. The increase in tryptone concentration resulted in an increase in the specific growth rate from 0.44 to 0.62 h(-1) and Y(ATP) from 12.5 to 18.5 mol ATP g dwt(-1). This study demonstrates that the auxo-accelerostat method, besides being an efficient tool for obtaining the culture characteristics, provides also decent conditions for the experiments elucidating the control mechanisms of cell growth.

Study of the toxic effect of short- and medium-chain monocarboxylic acids on the growth of Saccharomyces cerevisiae using the CO 2-auxo-accelerostat fermentation system

The effect of aliphatic monocarboxylic acids (formic, acetic, propionic, valeric, octanoic and decanoic acids) on the growth and metabolic activity of Saccharomyces cerevisiae S288C was studied, using continuous cultivation method — CO 2-auxo-accelerostat with smooth increase in the concentration of added monocarboxylic acids. Slow increase in the concentration of these acids resulted in the rapid decrease in the growth yield ( Y ATP) and specific growth rate ( μ), however, the specific ATP production rate ( Q ATP) increased or stayed almost constant. On the other hand, Q ATP decreased if the concentration of formic, acetic or decanoic acids was increased rapidly. The toxic effect of aliphatic monocarboxylic acids on the growth of S. cerevisiae was characterized and quantified from the respective dose–effect curves as the IC 50 value (mM) using two different endpoints: a decrease of 50% in the specific growth rate (IC 50 μ) and a decrease of 50% in the growth yield based on ATP production (IC 50YATP). The concentrations of formic, acetic, propionic, valeric, octanoic and decanoic acids causing the 50% reduction in the specific growth rate (IC 50μ) were, respectively, 18.1, 47.1, 33.6, 2.3, 0.16 and 0.07 mM. The IC 50 μ values were notably lower (up to 5-fold) in case of a more rapid increase in the concentration of acid in the medium. The results of the CO 2-auxo-accelerostat experiments show that the toxic effect depends not only on the nature of the monocarboxylic acid (lipophilicity) but also on the rate at which its concentration changes in the growth environment.

Fission yeast MO25 protein is localized at SPB and septum and is essential for cell morphogenesis

Cell morphogenesis is of fundamental significance in all eukaryotes for development, differentiation, and cell proliferation. In fission yeast, Drosophila Furry-like Mor2 plays an essential role in cell morphogenesis in concert with the NDR/Tricornered kinase Orb6. Mutations of these genes result in the loss of cell polarity. Here we show that the conserved proteins, MO25-like Pmo25, GC kinase Nak1, Mor2, and Orb6, constitute a morphogenesis network that is important for polarity control and cell separation. Intriguingly, Pmo25 was localized at the mitotic spindle pole bodies (SPBs) and then underwent translocation to the dividing medial region upon cytokinesis. Pmo25 formed a complex with Nak1 and was required for both the localization and kinase activity of Nak1. Pmo25 and Nak1 in turn were essential for Orb6 kinase activity. Further, the Pmo25 localization at the SPBs and the Nak1-Orb6 kinase activities during interphase were under the control of the Cdc7 and Sid1 kinases in the septation initiation network (SIN), suggesting a functional linkage between SIN and the network for cell morphogenesis/separation following cytokinesis.

Effect of oxythiamin on growth rate, survival ability and pyruvate decarboxylase activity in Saccharomyces cerevisiae.

Oxythiamin is one of the antivitamin derivatives of thiamin which, after phosphorylation, can be bound to the catalytic centre of thiamin-dependent enzymes and inhibit these enzymes. In this work the influence of oxythiamin on the growth rate, survival and the activity of pyruvate decarboxylase of Saccharomyces cerevisiae (s288c) was investigated. Oxythiamin decreased both the growth rate and survival ability of yeast cells. Moreover, in three-day-old cultures on a medium with oxythiamin, an increase of pyruvate decarboxylase activity was observed. This unusual effect may be in response to the earlier inhibition of pyruvate decarboxylase. A high concentration of pyruvate in the cell extracts taken from the medium with oxythiamin was found. This accumulation of pyruvate could provide for enhanced biosynthesis of the pyruvate decarboxylase apoform and an increase of enzyme activity.

L-proline as a nitrogen source increases the susceptibility of Saccharomyces cerevisiae S288c to fluconazole.

Fluconazole inhibition of Saccharomyces cerevisiae S288c growth was evaluated in media containing ammonia, L-proline or L-leucine as a nitrogen source. Growth inhibition by fluconazole was maximum when L-proline was used as a nitrogen source, while rhodamine 6G accumulation and fluconazole resistance were the highest when ammonia was the sole nitrogen source.

Designer deletion strains derived from Saccharomyces cerevisiae S288C: a useful set of strains and plasmids for PCR-mediated gene disruption and other applications.

A set of yeast strains based on Saccharomyces cerevisiae S288C in which commonly used selectable marker genes are deleted by design based on the yeast genome sequence has been constructed and analysed. These strains minimize or eliminate the homology to the corresponding marker genes in commonly used vectors without significantly affecting adjacent gene expression. Because the homology between commonly used auxotrophic marker gene segments and genomic sequences has been largely or completely abolished, these strains will also reduce plasmid integration events which can interfere with a wide variety of molecular genetic applications. We also report the construction of new members of the pRS400 series of vectors, containing the kanMX, ADE2 and MET15 genes.

Analysis of 21.7 kb DNA sequence from the left arm of chromosome VII reveals 11 open reading frames: two correspond to new genes.

The DNA sequence of a fragment of 21731 bp (nucleotides 87408 to 109138) located on the left arm of chromosome VII from Saccharomyces cerevisiae S288C has been determined using a random cloning strategy followed by an oligonucleotide-directed sequencing. This fragment contains eight complete genes previously sequenced (CLG1, SKI8, VAM7, YPT32, MIG2, SIP2, SPT16 and CHC1), the 5' part of POX1 and two other complete unidentified open reading frames of more than 100 amino acids.

Sequence of a 9.8 kb segment of yeast chromosome II including the three genes of the MAL3 locus and three unidentified open reading frames.

We report the DNA sequence of a segment located on the right arm of chromosome II from Saccharomyces cerevisiae S288C near the subtelomeric sequences. The sequence was determined using a random cloning strategy followed by an oligonucleotide-directed sequencing. The segment contains four non-overlapping open reading frames (ORFs) YBR297w, YBR298c, YBR299w and YBR301c, and two overlapping ones (YBR300c and YBR300w). Three of them--YBR297w, YBR298c and YBR299w--are the MAL3R (transcriptional regulatory protein), MAL3T (maltose permease) and MAL3S (maltase) genes of the MAL3 locus previously localized. The three other ORFs are unidentified. Another MAL locus (MALl) has been localized on chromosome VII. The Mal- phenotype of strain S288c cannot be explained by telomeric silencing.

Cytochrome P450 lanosterol 14α‐demethylase (ERG11) and manganese superoxide dismutase (SOD1) are adjacent genes in Saccharomyces cerevisiae

DNA sequencing and analysis of genomic DNA using the polymerase chain reaction were used to demonstrate that SOD1 and ERG11 are adjacent genes in Saccharomyces cerevisiae S288c and to establish the correct intergenic sequence of this segment on chromosome VIII.

A reduced specific ethanol‐forming performance of yeast at high biomass concentrations as a result of a changed ethanol‐tolerance behaviour of the cells under condition of limitation. II. Proving the effect in high‐flow rate fermentations with saccharomyces cerevisiae Sc 5

AbstractIn growth‐factor limited fermentations carried out in continuous high‐flow rate fermenters the relationship existing between the specific ethanol formation rate and the ethanol concentration was found to change its characteristics from a linear function into a nonlinear one at high biomass concentrations. The deviation from the linear inhibitory behaviour of the cells was the greater the more the biomass concentration increased.A very good correspondence between the experimentally found productivities of ethanol formation and its adequate values obtained by calculation could be attained by using an improved steady‐state productivity model, in which the variability of the function v = f(P) had been considered.