d-Xylose consumption by nonrecombinant Saccharomyces cerevisiae: A review

Xylose is the second most abundant sugar in nature. Its efficient fermentation has been considered as a critical factor for a feasible conversion of renewable biomass resources into biofuels and other chemicals. The yeast Saccharomyces cerevisiae is of exceptional industrial importance due to its excellent capability to ferment sugars. However, although S. cerevisiae is able to ferment xylulose, it is considered unable to metabolize xylose, and thus, a lot of research has been directed to engineer this yeast with heterologous genes to allow xylose consumption and fermentation. The analysis of the natural genetic diversity of this yeast has also revealed some nonrecombinant S. cerevisiae strains that consume or even grow (modestly) on xylose. The genome of this yeast has all the genes required for xylose transport and metabolism through the xylose reductase, xylitol dehydrogenase, and xylulokinase pathway, but there seems to be problems in their kinetic properties and/or required expression. Self-cloning industrial S. cerevisiae strains overexpressing some of the endogenous genes have shown interesting results, and new strategies and approaches designed to improve these S. cerevisiae strains for ethanol production from xylose will also be presented in this review.     

Genetic and enological analysis of selected Saccharomyces cerevisiae strains for wine production

The non‐wine Saccharomyces cerevisiae strain of 96581 was found to be a promising candidate for the production of white wine. It produced wines with fusel alcohols that were 57% higher than those produced by the wine yeasts studied and was also more efficient in the production of 2‐phenethyl acetate and 3‐methyl‐1‐butanol acetate. This study also shows that there is a difference in the ester‐formation efficiency for acetates relative to C6, C8 and C10 fatty acid esters for all the studied yeast strains. Therefore, it supports the view that other unidentified enzymes besides those regulated by ATF1 and ATF2 genes are involved in the production of ethyl esters of C6–C10 fatty acids. DNA analysis of the 25S, 18S, 5.8S and 5S ribosomal DNA genes in these strains showed high conservation. Despite the closely related nature of these yeast strains, the chemical profiles of the wines produced were significantly different.     

History of genome editing in yeast

For thousands of years humans have used the budding yeast Saccharomyces cerevisiae for the production of bread and alcohol; however, in the last 30–40 years our understanding of the yeast biology has dramatically increased, enabling us to modify its genome. Although S. cerevisiae has been the main focus of many research groups, other non‐conventional yeasts have also been studied and exploited for biotechnological purposes. Our experiments and knowledge have evolved from recombination to high‐throughput PCR‐based transformations to highly accurate CRISPR methods in order to alter yeast traits for either research or industrial purposes. Since the release of the genome sequence of S. cerevisiae in 1996, the precise and targeted genome editing has increased significantly. In this ‘Budding topic’ we discuss the significant developments of genome editing in yeast, mainly focusing on Cre‐loxP mediated recombination, delitto perfetto and CRISPR/Cas.     

Nutrient limitation leads to penetrative growth into agar and affects aroma formation in Pichia fabianii,P. kudriavzevii and Saccharomyces cerevisiae

Among fermentative yeast species, Saccharomyces cerevisiae is most frequently used as a model organism, although other yeast species may have special features that make them interesting candidates to apply in food‐fermentation processes. In this study, we used three yeast species isolated from fermented masau (Ziziphus mauritiana) fruit, S. cerevisiae 131, Pichia fabianii 65 and Pichia kudriavzevii 129, and determined the impact of nitrogen and/or glucose limitation on surface growth mode and the production of volatile organic compounds (VOCs). All three species displayed significant changes in growth mode in all nutrient‐limited conditions, signified by the formation of metafilaments or pseudohyphae. The timing of the transition was found to be species‐specific. Transition in growth mode is suggested to be linked to the production of certain fusel alcohols, such as phenylethyl alcohol, which serve as quorum‐sensing molecules. Interestingly, we did not observe concomitant increased production of phenylethyl alcohol and filamentous growth. Notably, a broader range of esters was found only for the Pichia spp. grown on nitrogen‐limited agar for 21 days compared to nutrient‐rich agar, and when grown on glucose‐ and glucose‐ plus nitrogen‐limited agar. Our data suggest that for the Pichia spp., the formation of esters may play an important role in the switch in growth mode upon nitrogen limitation. Further biological or ecological implications of ester formation are discussed. Copyright © 2014 John Wiley & Sons, Ltd.     

Fermentation Characteristics and Aromatic Profile of Plum Wines Produced with Indigenous Microbiota and Pure Cultures of Selected Yeast

The aim of this study was to assess and compare fermentation characteristics and aromatic profile of plum wines produced with indigenous microbiota and pure cultures of different selected yeast. Experiments were carried out with plum (Prunus domestica L.) varieties of different fruit ripening times (?a?anska rana, ?a?anska lepotica, and Po?ega?a). Wine fermentations were conducted by the activity of indigenous microbiota, commercially available Saccharomyces cerevisiae and Saccharomyces bayanus yeast strains and joint activity of Schizosaccharomyces pombe and S. cerevisiae (sequential inoculation). Statistically significant differences in fermentative characteristics and the content of certain volatile compounds were observed as a result of metabolic activity of various indigenous and/or selected yeasts during fermentation of plum pomace. Minimal duration of fermentation (4 to 5 d) and fastest ethanol production rate (from 12.3 to 15.5 g/L/d) were the characteristics of the studied S. cerevisiae strains. Isobutanol, 3‐methyl‐1‐butanol, 1‐heptanol, and 1‐octanol were the most prevalent higher alcohols in the tested plum wine samples. The predominant ester in plum wines was ethyl acetate, ethyl lactate, amyl acetate, isoamyl acetate, and ethyl palmitate, esters responsible for the floral and fruity olfactory tones, were also present in large amounts. Also, the use of S. cerevisiae strains resulted in the production of plum wines with better sensory characteristics than ones produced with other investigated yeasts. Obtained results are significant since there is limited data on the compounds responsible for the unique flavor of plum wine, as well as on the impact of different yeast starter cultures application on the overall quality of fruit wines.     

Isolation of a Histoplasma capsulatum cDNA that complements a mitochondrial NAD(+)‐isocitrate dehydrogenase subunit I‐deficient mutant of Saccharomyces cerevisiae

A cDNA library was prepared from Histoplasma capsulatum strain G‐217B yeast cells and an apparently full‐length cDNA for a subunit of the citric acid cycle enzyme NAD(+)‐isocitrate dehydrogenase was identified by sequence analysis. Its predicted amino acid sequence is more similar to the IDH1 regulatory subunit of S. cerevisiae NAD(+)‐isocitrate dehydrogenase than to the IDH2 catalytic subunit. After expression in S. cerevisiae from an S. cerevisiae promoter, it was shown to functionally complement an S. cerevisiae idh1 mutant, but not an idh2 mutant, for growth on acetate as a carbon source and for production of NAD(+)‐isocitrate dehydrogenase enzyme activity. These results confirm that the H. capsulatum cDNA encodes a homologue of subunit I of the S. cerevisiae mitochondrial isocitrate dehydrogenase isozyme that functions in the citric acid cycle. The HcIDH1 cDNA sequence is available in GenBank with Accession No. AF009036. Copyright © 1999 John Wiley & Sons, Ltd.     

Fermentation Process and Grain Structure of Baked Breads from Frozen Dough Using Freeze-Tolerant Yeasts

The fermentation process for frozen doughs using freeze‐sensitive (Saccharomyces cerevisiae, Kyowa for sweet bread; S. cerevisiae, FC for white bread) and freeze‐tolerant (S. cerevisiae, YF for sweet bread) yeasts was traced by magnetic resonance imaging (MRI). Grain network structures of baked breads were also visualized by MRI. Prefermentation before freezing, punching and remolding, or resheeting and molding treatments increased loaf volume by 10 to 110% for the baked breads using freeze‐tolerant yeast, while these treatments decreased loaf volume by 70% using freeze‐sensitive yeast. The first fermentation before freezing and the second fermentation with punching or resheeting after thawing are useful for obtaining good quality breads from frozen dough using freeze‐tolerant yeast.     

Bioconversion of heptanal to heptanol by Saccharomyces cerevisiae

Saccharomyces cerevisiae is widely known for its catalytic activity on substrates such as aldehyde and ketone. Interestingly, the activity of S. cerevisiae on heptanal (C₆H₁₃CHO), in spite of its being a very common aldehyde, has not been explored. The main objective of this study was therefore to investigate the bioconversion of heptanal, using a strain of the yeast S. cerevisiae. Bioconversion parameters such as incubation period, pH, concentration of substrate, yeast and maltose were also optimized. The study revealed heptanol as the major product. The optimum conditions for biotransformation were found to be: 3 days incubation; pH 7.0; heptanal concentration 0.15 ml/100 ml medium; and S. cerevisiae concentration of 0.15 g/100 ml medium. Reduction in maltose content (to 0.3 g maltose/100 ml medium) showed increased conversion of heptanal. Heptanoic acid and 2‐hydroxyheptanoic acid were obtained as two minor co‐products. The overall study showed that S. cerevisiae converted heptanal to heptanol by a yield of 68.9 ± 1.1% w/w under optimum conditions. Copyright © 2010 John Wiley & Sons, Ltd.     

Improvement of growth,fermentative efficiency and ethanol tolerance of Kloeckera africana during the fermentation of Agave tequilana juice by addition of yeast extract

BACKGROUND: The aim of this work was to improve the productivity and yield of tequila fermentation and to propose the use of a recently isolated non‐Saccharomyces yeast in order to obtain a greater diversity of flavour and aroma of the beverage. For that, the effects of the addition of different nitrogen (N) sources to Agave tequilana juice on the growth, fermentative capacity and ethanol tolerance of Kloeckera africana and Saccharomyces cerevisiae were studied and compared. RESULTS: Kloeckera africana K1 and S. cerevisiae S1 were cultured in A. tequilana juice supplemented with ammonium sulfate, diammonium phosphate or yeast extract. Kloeckera africana did not assimilate inorganic N sources, while S. cerevisiae utilised any N source. Yeast extract stimulated the growth, fermentative capacity and alcohol tolerance of K. africana, giving kinetic parameter values similar to those calculated for S. cerevisiae. CONCLUSION: This study revealed the importance of supplementing A. tequilana juice with a convenient N source to achieve fast and complete conversion of sugars in ethanol, particularly in the case of K. africana. This yeast exhibited similar growth and fermentative capacity to S. cerevisiae. The utilisation of K. africana in the tequila industry is promising because of its variety of synthesised aromatic compounds, which would enrich the attributes of this beverage. Copyright © 2009 Society of Chemical Industry     

Investigating flavour characteristics of British ale yeasts: techniques,resources and opportunities for innovation

Five British ale yeast strains were subjected to flavour profiling under brewery fermentation conditions in which all other brewing parameters were kept constant. Significant variation was observed in the timing and quantity of flavour‐related chemicals produced. Genetic tests showed no evidence of hybrid origins in any of the strains, including one strain previously reported as a possible hybrid of Saccharomyces cerevisiae and S. bayanus. Variation maintained in historical S. cerevisiae ale yeast collections is highlighted as a potential source of novelty in innovative strain improvement for bioflavour production. Copyright © 2014 John Wiley & Sons, Ltd.     

The Influence of Inoculum Level on Fermentation and Flavour Compounds of White Wines Made from cv. Emir

In this study, the influence of the addition of a commercial wine yeast (Saccharomyces cerevisiae) at inocula of 1 × 10⁴ to 1 × 10⁷ cells/ml in Emir must was investigated with a focus on yeast growth, fermentation rate, ethyl alcohol and flavour compound formation. Spontaneous fermentation without inoculation was also performed. Higher peak counts were observed with higher amounts of S. cerevisiae yeast. Addition of various amounts of yeast led to the earlier disappearance of non‐Saccharomyces yeasts. The fermentation rate was improved with higher amounts of yeast, but ethanol production was not affected. Concentrations of higher alcohols increased with increasing inoculum levels, especially inoculum sizes of 1 × 10⁶ cells/ml and 1 × 10⁷ cells/ml. The amount of ethyl acetate was reduced with increased inoculum levels.     

Breeding of lager yeast with Saccharomyces cerevisiae improves stress resistance and fermentation performance

Lager beer brewing relies on strains collectively known as Saccharomyces carlsbergensis, which are hybrids between S. cerevisiae and S. eubayanus‐like strains. Lager yeasts are particularly adapted to low‐temperature fermentations. Selection of new yeast strains for improved traits or fermentation performance is laborious, due to the allotetraploid nature of lager yeasts. Initially, we have generated new F1 hybrids by classical genetics, using spore clones of lager yeast and S. cerevisiae and complementation of auxotrophies of the single strains upon mating. These hybrids were improved on several parameters, including growth at elevated temperature and resistance against high osmolarity or high ethanol concentrations. Due to the uncertainty of chromosomal make‐up of lager yeast spore clones, we introduced molecular markers to analyse mating‐type composition by PCR. Based on these results, new hybrids between a lager and an ale yeast strain were isolated by micromanipulation. These hybrids were not subject to genetic modification. We generated and verified 13 hybrid strains. All of these hybrid strains showed improved stress resistance as seen in the ale parent, including improved survival at the end of fermentation. Importantly, some of the strains showed improved fermentation rates using 18°Plato at 18–25°C. Uniparental mitochondrial DNA inheritance was observed mostly from the S. cerevisiae parent. Copyright © 2012 John Wiley & Sons, Ltd.     

A study on Saccharomyces cerevisiae and Candida utilis cell wall capacity for binding magnesium

The capacity for binding magnesium by bakery's yeast strain Saccharomyces cerevisiae No. 102 (Pure Culture Collection, Faculty Food Technology, Warsaw) and fodder yeast strain Candida utilis (ATCC 9950) was investigated in media supplemented with that element. The capacities of C. utilis (ATCC 9950) and S. cerevisiae (No. 102) biomass for binding magnesium were not statistically different in the first 24 h. In the next 24 h of cultivation the cells of C. utilis (ATCC 9950) were still able to bind magnesium ions, whereas those of S. cerevisiae (No. 102) released a part of previously bound magnesium to the medium. The major part of magnesium bound by the cells of C. utilis (ATCC 9950) was accumulated in cytosole. It was opposite to the cells of bakery yeast S. cerevisiae (No. 102) that accumulated magnesium mainly in the cell wall. The cells of C. utilis (ATCC 9950) yeast were smaller and their cell walls were thinner as compared to those of S. cerevisiae (No. 102) yeast. The thickness of the external mannoprotein layers was similar in both strains analyzed.     

Oxylipin Associated Co‐Flocculation in Yeasts

According to the lectin‐theory, the yeast Schizosaccharomyces pombe lacks the specific receptors (α‐mannans) necessary to facilitate co‐flocculation with Saccharomyces cerevisiae species. In this study we demonstrate oxylipin associated co‐flocculation between Sacch. cerevisiae and S. pombe strains using differential cell staining, immunofluoresence and ultrastructural studies. Using a 3‐hydroxy (OH) oxylipin specific antibody coupled to a fluorescing compound, 3‐OH oxylipins were found to be present on the cell surfaces of Sacch. cerevisiae and S. pombe. The presence of 3‐OH oxylipins was confirmed using gas chromatography‐mass spectrometry. Strikingly, when acetylsalicylic acid (aspirin), a 3‐OH oxylipins inhibitor, was added to Sacch. cerevisiae which was then mixed with S. pombe strains grown in complex media, co‐flocculation was significantly inhibited. We conclude that aspirin‐sensitive 3‐OH 8:0 is probably involved in co‐flocculation.     

Use of PCR‐DHPLC (Polymerase Chain Reaction—Denaturing High Performance Liquid Chromatography) for the Rapid Differentiation of Industrial Saccharomyces pastorianus and Saccharomyces cerevisiae Strains

Strain specific detection and control of Saccharomyces pastorianus and Saccharomyces cerevisiae starter cultures is of great importance for the fermentation industry. The preconditions of strain specific fermentation characteristics can be ensured by periodic analysis and confirmation of the strain identity. With regard to industrial S. pastorianus and S. cerevisiae strains and a focus on brewing strains, the differentiation methods most available are time‐consuming and not very discriminative. In this work PCR‐DHPLC analysis was investigated as a novel approach for the differentiation of industrially used S. pastorianus and S. cerevisiae strains. The PCR‐DHPLC‐system was specific for S. cerevisiae strains and S. pastorianus hybrid strains that contain IGS2 rDNA, which originates from the S. cerevisiae ancestor. For the DNA of 177 strains of 41 non‐target species, which are typical for beverage and fermentation surroundings, the absence of PCR‐amplificates could be confirmed by DHPLC analysis. It was shown that single strains of S. cerevisiae and S. pastorianus could be differentiated. A strain specific differentiation within the group of top‐fermenting Saccharomyces cerevisiae strains could also be performed. For the group of bottom fermenting S. pastorianus brewing strains, strain‐to‐strain specific differences in the DHPLC chromatograms could be observed which can be used to differentiate and to compare two single strains with each other, although the comparison of chromatograms of an unknown S. pastorianus strain with a set of known S. pastorianus chromatograms could only reveal tendencies towards grouping into types. The differential DHPLC chromatogram characteristics (fluorescence intensities, number of peaks/side‐peaks/peak‐shoulders) within S. pastorianus are present, but not as distinctive as for S. cerevisiae. Additionally PCR‐DHPLC has advantages compared to other differentiation methods, such as species specificity, speed (2.5 h for one sample) and precision with the described limits.     

CRISPR/Cas9-RNA interference system for combinatorial metabolic engineering of Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is widely used in industrial biotechnology for the production of fuels, chemicals, food ingredients, food and beverages, and pharmaceuticals. To obtain high-performing strains for such bioprocesses, it is often necessary to test tens or even hundreds of metabolic engineering targets, preferably in combinations, to account for synergistic and antagonistic effects. Here, we present a method that allows simultaneous perturbation of multiple selected genetic targets by combining the advantage of CRISPR/Cas9, in vivo recombination, USER assembly and RNA interference. CRISPR/Cas9 introduces a double-strand break in a specific genomic region, where multiexpression constructs combined with the knockdown constructs are simultaneously integrated by homologous recombination. We show the applicability of the method by improving cis,cis-muconic acid production in S. cerevisiae through simultaneous manipulation of several metabolic engineering targets. The method can accelerate metabolic engineering efforts for the construction of future cell factories.     

Relationship between growth of food‐spoilage yeast in high‐sugar environments and sensitivity to high‐intensity pulsed UV light irradiation

The relationship between prior growth of food‐spoilage yeast in high‐sugar environments and their subsequent survival postpulsed UV (PUV) irradiation was investigated. Test yeast were separately grown to early stationary phase in YPD broth containing increasing concentrations of glucose (1–50% w/v) and were flashed with ≤40 pulses of broad‐spectrum light at lamp discharge energy settings of 3.2, 7.2 and 12.8 J (equivalent to UV doses of 0.53, 1.09 and 3.36 μJ cm^?2, respectively) and their inactivation measured. Findings showed that prior growth in high‐sugar conditions (≥30% glucose w/v) enhanced the sensitivity of all nine representative strains of Zygosaccharomyces bailii, Z. rouxii and Saccharomyces cerevisiae yeast to PUV irradiation. Significant differences in inactivation amongst different yeast types also occurred depending on amount of UV dose applied, where the order of increasing sensitivity of osmotically stressed yeast to PUV irradiation was shown to be Z. rouxii, Z. bailii and >S. cerevisiae. For example, a 1.2‐log order difference in CFU mL^?1 reduction occurred between Z. bailii 11 486 and S. cerevisiae 834 when grown in 50% w/v sugar samples and treated with the uppermost test UV dosage of 3.36 μJ cm^?2, where these two yeast strains were reduced by 3.8 and 5.0 log orders, respectively, after this PUV treatment regime compared to untreated controls. The higher the UV dose applied the greater the reduction in yeast numbers. For example, a 1.0‐, 1.4‐ and 4.0‐log order differences in CFU mL^?1 numbers occurred for S. cerevisiae 834 grown in 15% w/v sugar samples and then treated with PUV dose of 0.53, 1.09 and 3.36 μJ cm^?2, respectively. These findings support the development of PUV for the treatment of high‐sugar foods that are prone to spoilage by osmotolerant yeast.