From yeast genetics to biotechnology

Removal of undesirable genes using yeast backcrossing

4-Vinylguaiacol (4-VG) is one of the causative compounds for the phenolic odor characteristics of brewed liquor. In the case of Japanese sake brewing, 4-VG is formed through the decarboxylation of ferulic acid produced by rice koji enzymes from steamed rice. PAD1 (phenylacrylic acid decarborxylase gene) and FDC1 (ferulic acid decarboxylase gene) genes are essential for decarboxylation of ferulic acid in Saccharomyces cerevisiae and the single polymorphisms of both genes show a relationship with ferulic acid decarboxylation ability. While most of the Kyokai yeasts distributed by the Brewing Society of Japan have homozygous non-function fdc1 alleles, many newly isolated natural yeasts for local specialities carry the wild-type FDC1 gene. In our previous research, we found that a crossbreed strain lost a significant amount of chromosomal DNA as it underwent meiosis-like adaptation. Here, we established a breeding approach to exclude undesirable gene alleles (such as the wild-type FDC1 genes) from yeast strains of interest by backcrossing using Kyokai yeasts. Homozygous fdc1 crossbreeds were generated through the three rounds of crossing procedures, and we confirmed the reduction of 4-VG in the culture supernatant of the homozygous fdc1 hybrid strain compared to the parental strain. Importantly, this approach does not include growth selection for the mutation of interest (the fdc1 mutant in the current case). Using various yeast strains generated throughout human history, it may become possible to design and build any yeast strains according to the purpose.

The yeast sphingolipid signaling landscape

Sphingolipids are recognized as signaling mediators in a growing number of pathways, and represent potential targets to address many diseases. The study of sphingolipid signaling in yeast has created a number of breakthroughs in the field, and has the potential to lead future advances. The aim of this article is to provide an inclusive view of two major frontiers in yeast sphingolipid signaling. In the first section, several key studies in the field of sphingolipidomics are consolidated to create a yeast sphingolipidome that ranks nearly all known sphingolipid species by their level in a resting yeast cell. The second section presents an overview of most known phenotypes identified for sphingolipid gene mutants, presented with the intention of illuminating not yet discovered connections outside and inside of the field.

Development of growth selection systems to isolate a-type or α-type of yeast cells spontaneously emerging from MATa/α diploids

BACKGROUND

Manufacture of MATa and MATα yeast cells is required for crossbreeding, a procedure that permits hybridization and the generation of new heterozygous strains. Crossbreeding also can be performed with a- and α-type of cells, which have the same mating abilities as MATa and MATα haploid cells, respectively.

RESULTS

In this work, we describe a method to generate a- and α-type of cells via the naturally-occurring chromosomal aberration in parental MATa/α diploids. We successfully designed suitable genetic circuits for expression of the URA3 selection marker gene to permit isolation of a- and α-type of cells, respectively, on solid medium lacking uracil. Furthermore we succeeded in generation of zygotes by mating of both the manufactured a- and α-type of yeast cells.

CONCLUSIONS

This process does not require exposure to mutagens such as UV irradiation, thereby avoiding the accumulation of undesirable mutations that would detract from the valuable traits that are under study. All the genetic modifications in the current study were introduced into yeast cells using plasmids, meaning that these traits can be removed without altering the genome sequence. This approach provides a reliable and versatile tool for scientific research and industrial yeast crossbreeding.

Gene copy number and polyploidy on products formation in yeast

Yeast, such as Saccharomyces cerevisiae or Kluyveromyces lactis is appropriate strain for ethanol production or some useful compounds production. Cellulases expressing yeast can ferment ethanol from cellulosic materials; however, the productivity should be increase more and more. To improve and engineer the productivity, the target gene(s) were introduced into yeast genome. Generally, using genetic engineering, increasing integrated gene numbers are increased, the expressed protein ability such as enzymatic activities are also increased. In this mini-review, we focused on the effect of integrated gene copy number and the polyploidy on the productivity such as enzymatic activity and/or product yield.

Progress in metabolic engineering of Saccharomyces cerevisiae

The traditional use of the yeast Saccharomyces cerevisiae in alcoholic fermentation has, over time, resulted in substantial accumulated knowledge concerning genetics, physiology, and biochemistry as well as genetic engineering and fermentation technologies. S. cerevisiae has become a platform organism for developing metabolic engineering strategies, methods, and tools. The current review discusses the relevance of several engineering strategies, such as rational and inverse metabolic engineering, evolutionary engineering, and global transcription machinery engineering, in yeast strain improvement. It also summarizes existing tools for fine-tuning and regulating enzyme activities and thus metabolic pathways. Recent examples of yeast metabolic engineering for food, beverage, and industrial biotechnology (bioethanol and bulk and fine chemicals) follow. S. cerevisiae currently enjoys increasing popularity as a production organism in industrial ("white") biotechnology due to its inherent tolerance of low pH values and high ethanol and inhibitor concentrations and its ability to grow anaerobically. Attention is paid to utilizing lignocellulosic biomass as a potential substrate.

A homozygous diploid subset of commercial wine yeast strains

Genetic analysis was performed on 45 commercial yeasts which are used in winemaking because of their superior fermentation properties. Genome sizes were estimated by propidium iodide fluorescence and flow cytometry. Forty strains had genome sizes consistent with their being diploid, while five had a range of aneuploid genome sizes that ranged from 1.2 to 1.8 times larger. The diploid strains are all Saccharomyces cerevisiae, based on genetic analysis of microsatellite and minisatellite markers and on DNA sequence analysis of the internal transcribed spacer (ITS) region of nuclear ribosomal DNA of four strains. Four of the five aneuploid strains appeared to be interspecific hybrids between Saccharomyces kudriavzevii and Saccharomyces cerevisiae, with the fifth a hybrid between two S. cerevisiae strains. An identification fingerprint was constructed for the commercial yeast strains using 17 molecular markers. These included six published trinucleotide microsatellites, seven new dinucleotide microsatellites, and four published minisatellite markers. The markers provided unambiguous identification of the majority of strains; however, several had identical or similar patterns, and likely represent the same strain or mutants derived from it. The combined use of all 17 polymorphic loci allowed us to identify a set of eleven commercial wine yeast strains that appear to be genetically homozygous. These strains are presumed to have undergone inbreeding to maintain their homozygosity, a process referred to previously as 'genome renewal'.

Direct mating between diploid sake strains of Saccharomyces cerevisiae

Various auxotrophic mutants of diploid heterothallic Japanese sake strains of Saccharomyces cerevisiae were utilized for selecting mating-competent diploid isolates. The auxotrophic mutants were exposed to ultraviolet (UV) irradiation and crossed with laboratory haploid tester strains carrying complementary auxotrophic markers. Zygotes were then selected on minimal medium. Sake strains exhibiting a MATa or MATalpha mating type were easily obtained at high frequency without prior sporulation, suggesting that the UV irradiation induced homozygosity at the MAT locus. Flow cytometric analysis of a hybrid showed a twofold higher DNA content than the sake diploid parent, consistent with tetraploidy. By crossing strains of opposite mating type in all possible combinations, a number of hybrids were constructed. Hybrids formed in crosses between traditional sake strains and between a natural nonhaploid isolate and traditional sake strains displayed equivalent fermentation ability without any apparent defects and produced comparable or improved sake. Isolation of mating-competent auxotrophic mutants directly from industrial yeast strains allows crossbreeding to construct polyploids suitable for industrial use without dependence on sporulation.

A laboratory yeast strain suitable for spirit production

Yeast strains of the species Saccharomyces cerevisiae currently in use for the production of consumable alcohols such as beer, wine and spirits are genetically largely undefined. This prevents the use of standard genetic manipulations, such as crossings and tetrad analysis, for strain improvement. Furthermore, it complicates the application of the majority of modern methods developed in yeast molecular biology. Here we used two haploid laboratory strains with suitable auxotrophic markers for the construction of a genetically well defined, prototrophic diploid production strain. This strain was tested for its fermentative and sensory performances in comparison to commercially available yeasts. Three different fruit mashes (cherries, plums and pears) were fermented in a 90 kg scale. These were then subjected to distillation and used for the production of spirits with a final ethanol content of 40% (v/v). Fermentation parameters assayed included growth, sugar utilization, ethanol production and generation of volatile compounds, higher alcohols and glycerol. The spirits were also tested for their sensory performances and the data obtained statistically consolidated. Our results clearly demonstrate that this laboratory strain does not display any disadvantage compared with commercial yeasts in spirit production for any of the parameters tested, yet it offers the potential to apply both classical breeding and modern molecular genetic techniques for adjusting yeast physiology to special production schemes.

Influence of carbon source and surface hydrophobicity on the aggregation of the yeastKluyveromyces bulgaricus

Aggregation of the yeast Kluyveromyces bulgaricus is mediated by the galactose-specific lectin KbCWL1. This lectin contains hydrophobic amino acids and its activity is calcium dependent. A specific fluorescent probe, 1-anilinonaphthalene-8-sulfonic acid in the free acid form (ANS; Sigma Chemical Co., St. Louis, Missouri), was used to study the hydrophobic areas on the cellular surface of K. bulgaricus. Changes in surface hydrophobicity during the growth and aggregation of yeast cells were studied. Surface hydrophobicity increased during growth and depended on the amount of yeast cells in the culture medium. During growth, the size of the hydrophobic areas on the cell surface was measured using ANS and was found to increase with the percentage of flocculating yeasts. Our results strongly suggest that the hydrophobic areas of the cell walls of yeast cells are involved in the aggregation of K. bulgaricus.Key words: aggregation, carbon source, fluorescence probe, hydrophobicity, yeast.