Exploring the correlation of metabolites changes and microbial succession in solid-state fermentation of Sichuan Sun-dried vinegar.

BACKGROUND: The traditional Sichuan Sun-dried vinegar (SSV) with unique flavor and taste is believed to be generated by the solid-state fermentation craft. However, how microorganisms and their metabolites change along with fermentation has not yet been explored. RESULTS: In this study, our results demonstrated that the middle and late stages of SSV fermentation were the periods showing the largest accumulation of organic acids and amino acids. Furthermore, in the bacterial community, the highest average relative abundance was Lactobacillus (ranging from 37.55 to 92.50%) in all fermentation stages, while Acetobacters ranked second position (ranging from 20.15 to 0.55%). The number of culturable lactic acid bacteria is also increased during fermentation process (ranging from 3.93 to 8.31 CFU/g). In fungal community, Alternaria (29.42%), Issatchenkia (37.56%) and Zygosaccharomyces (69.24%) were most abundant in different fermentation stages, respectively. Interestingly, Zygosaccharomyces, Schwanniomyces and Issatchenkia were first noticed as the dominant yeast genera in vinegar fermentation process. Additionally, spearman correlation coefficients exhibited that Lactobacillus, Zygosaccharomyces and Schwanniomyces were significant correlation with most metabolites during the fermentation, implying that these microorganisms might make a significant contribution to the flavor formation of SSV. CONCLUSION: The unique flavor of SSV is mainly produced by the core microorganisms (Lactobacillus, Zygosaccharomyces and Schwanniomyces) during fermentation. This study will provide detailed information related to the structure of microorganism and correlation between changes in metabolites and microbial succession in SSV. And it will be very helpful for proposing a potential approach to monitor the traditional fermentation process.

Metabolomics analysis of salt tolerance of Zygosaccharomyces rouxii and guided exogenous fatty acid addition for improved salt tolerance.

BACKGROUND: Zygosaccharomyces rouxii plays an irreplaceable role in the manufacture of traditional fermented foods, which are produced in a high-salt environment. However, there is little research on strategies for improving salt tolerance of Z. rouxii. RESULTS: In this study, metabolomics was used to reveal the changes in intracellular metabolites under salt stress, and the results show that most of the carbohydrate contents decreased, the contents of xanthohumol and glycerol increased (fold change 4.07 and 5.35, respectively), while the contents of galactinol, xylitol and d-threitol decreased (fold change -9.43, -5.83 and -3.59, respectively). In addition, the content of four amino acids and six organic acids decreased, while that of the ten nucleotides increased. Notably, except for stearic acid (C18:0), all fatty acid contents increased. Guided by the metabolomics results, the effect of addition of seven exogenous fatty acids (C12:0, C14:0, C16:0, C18:0, C16:1, C18:1, and C18:2) on the salt tolerance of Z. rouxii was analyzed, and the results suggested that four exogenous fatty acids (C12:0, C16:0, C16:1, and C18:1) can increase the biomass yield and maximum growth rate. Physiological analyses demonstrated that exogenous fatty acids could regulate the distribution of fatty acids in the cell membrane, increase the degree of unsaturation, improve membrane fluidity, and maintain cell integrity, morphology and surface roughness. CONCLUSION: These results are applicable to revealing the metabolic mechanisms of Z. rouxii under salt stress and screening potential protective agents to improve stress resistance by adding exogenous fatty acids. © 2022 Society of Chemical Industry.

Regulation of mating and mating-type-specific genes in Zygosaccharomyces sp. yeast.

Zygosaccharomyces sp. is an industrially important yeast for the production traditional fermented foods in Japan. At present, however, there is no easy method for mating Zygosaccharomyces sp. strains in the laboratory; furthermore, little is known about the expression of mating-type-specific genes in this yeast. Here, mating was observed when Zygosaccharomyces sp. was subjected to nitrogen-starvation conditions. The expression of mating-type-specific genes, Zygo STE6 and Zygo MFα1, was induced under nitrogen-starvation conditions, as confirmed by lacZ reporter assay. This expression was mating-type-specific: Zygo STE6 was expressed specifically for mating-type a, whereas and Zygo MFα1 was expressed specifically for mating-type α. Yeast strains Zygosaccharomyces rouxii DL2 and DA2, derived from type strain Z. rouxii CBS732, did not show mating even under nitrogen-starvation conditions. Gene sequencing revealed that the Zygo STE12 in Z. rouxii CBS732 has a frameshift mutation. Under nitrogen starvation, mating was observed in both DL2 and DA2 transformed with the wild-type Zygo STE12. The expression of Zygo STE6 in Z. rouxii DL2 transformed with wild-type Zygo STE12 under nitrogen-starvation conditions was confirmed by lacZ reporter assay. Collectively, these results revealed that, under nitrogen-starvation conditions, Zygosaccharomyces sp. can mate and mating-type-specific genes are expressed. Furthermore, Zygo Ste12 is essential for both mating and the expression of mating-type-specific genes in Zygosaccharomyces sp.

Hsp90 regulates nongenetic variation in response to environmental stress.

Nongenetic cell-to-cell variability often plays an important role for the survival of a clonal population in the face of fluctuating environments. However, the underlying mechanisms regulating such nongenetic heterogeneity remain elusive in most organisms. We report here that a clonal yeast population exhibits morphological heterogeneity when the level of Hsp90, a molecular chaperone, is reduced. The morphological heterogeneity is driven by the dosage of Cdc28 and Cla4, a key regulator of septin formation. Low Hsp90 levels reduce Cla4 protein stability and cause a subpopulation of cells to switch to a filamentous form that has been previously suggested to be beneficial under certain hostile environments. Moreover, Hsp90-dependent morphological heterogeneity can be induced by environmental stress and is conserved across diverse yeast species. Our results suggest that Hsp90 provides an evolutionarily conserved mechanism that links environmental stress to the induction of morphological diversity.

Physiological Genomics of the Highly Weak-Acid-Tolerant Food Spoilage Yeasts of Zygosaccharomyces bailii sensu lato.

Zygosaccharomyces bailii and two closely related species, Z. parabailii and Z. pseudobailii ("Z. bailii species complex", "Z. bailii sensu lato" or simply "Z. bailii (s.l.)"), are frequently implicated in the spoilage of acidified preserved foods and beverages due to their tolerance to very high concentrations of weak acids used as food preservatives. The recent sequencing and annotation of these species' genomes have clarified their genomic organization and phylogenetic relationship, which includes events of interspecies hybridization. Mechanistic insights into their adaptation and tolerance to weak acids (e.g., acetic and lactic acids) are also being revealed. Moreover, the potential of Z. bailii (s.l.) to be used in industrial biotechnological processes as interesting cell factories for the production of organic acids, reduction of the ethanol content, increase of alcoholic beverages aroma complexity, as well as of genetic source for increasing weak acid resistance in yeast, is currently being considered. This chapter includes taxonomical, ecological, physiological, and biochemical aspects of Z. bailii (s.l.). The focus is on the exploitation of physiological genomics approaches that are providing the indispensable holistic knowledge to guide the effective design of strategies to overcome food spoilage or the rational exploitation of these yeasts as promising cell factories.

A set of plasmids carrying antibiotic resistance markers and Cre recombinase for genetic engineering of nonconventional yeast Zygosaccharomyces rouxii.

The so-called nonconventional yeasts are becoming increasingly attractive in food and industrial biotechnology. Among them, Zygosaccharomyces rouxii is known to be halotolerant, osmotolerant, petite negative, and poorly Crabtree positive. These traits and the high fermentative vigour make this species very appealing for industrial and food applications. Nevertheless, the biotechnological exploitation of Z. rouxii has been biased by the low availability of genetic engineering tools and the recalcitrance of this yeast towards the most conventional transformation procedures. Centromeric and episomal Z. rouxii plasmids have been successfully constructed with prototrophic markers, which limited their usage to auxotrophic strains, mainly derived from the Z. rouxii haploid type strain Centraalbureau voor Schimmelcultures (CBS) 732T . By contrast, the majority of industrially promising Z. rouxii yeasts are prototrophic and allodiploid/aneuploid strains. In order to expand the genetic tools for manipulating these strains, we developed two centromeric and two episomal vectors harbouring KanMXR and ClonNATR as dominant drug resistance markers, respectively. We also constructed the plasmid pGRCRE that allows the Cre recombinase-mediated marker recycling during multiple gene deletions. As proof of concept, pGRCRE was successfully used to rescue the kanMX-loxP module in Z. rouxii ATCC 42981 G418-resistant mutants previously constructed by replacing the MATαP expression locus with the loxP-kanMX-loxP cassette.

Effect of raw material and starters on the metabolite constituents and microbial community diversity of fermented soy sauce.

BACKGROUND: The quality of soy sauce is strongly affected by microorganisms and raw materials (defatted soybean or whole soybean). The present study investigated the effect of two types of fortified pattern, including inoculation with starters (Tetragenococcus halophilus combined with Zygosaccharomyces rouxii and Candida versatilis), and adding culture medium (saccharified rice flour solution), on the metabolite profiles and microbial community of soy sauce produced from defatted soybean (DP) and whole soybean (HD). Relationships between microbes and volatiles, and their interactions, were shown. RESULTS: The dominant metabolites differed in the soy sauce samples except for isoflavones. Alcohols and phenols were higher in DP moromi. Two classes of dominant esters, long-chain fatty acid esters (LFAE) and unsaturated-short-chain fatty acid esters (USFAE), were higher in HD moromi than DP. Weissella, Leuconostoc, and Aspergillus were the dominant microbes. Leuconostoc, and Aspergillus increased, and Weissella decreased in moromi inoculated with starters compared with a control. Similar changes to Leuconostoc were observed in moromi added culture medium. CONCLUSIONS: The microbes were responsible for the formation of volatiles. The intergeneric interactions with microbes were affected by fortified pattern. The effect of starters or culture medium on microbial community and metabolites of soy sauce depended on the raw material. © 2019 Society of Chemical Industry.

The Zygosaccharomyces bailii transcription factor Haa1 is required for acetic acid and copper stress responses suggesting subfunctionalization of the ancestral bifunctional protein Haa1/Cup2.

BACKGROUND: The food spoilage yeast species Zygosaccharomyces bailii exhibits an extraordinary capacity to tolerate weak acids, in particular acetic acid. In Saccharomyces cerevisiae, the transcription factor Haa1 (ScHaa1) is considered the main player in genomic expression reprogramming in response to acetic acid stress, but the role of its homologue in Z. bailii (ZbHaa1) is unknown. RESULTS: In this study it is demonstrated that ZbHaa1 is a ScHaa1 functional homologue by rescuing the acetic acid susceptibility phenotype of S. cerevisiae haa1Δ. The disruption of ZbHAA1 in Z. bailii IST302 and the expression of an extra ZbHAA1 copy confirmed ZbHAA1 as a determinant of acetic acid tolerance. ZbHaa1 was found to be required for acetic acid stress-induced transcriptional activation of Z. bailii genes homologous to ScHaa1-target genes. An evolutionary analysis of the Haa1 homologues identified in 28 Saccharomycetaceae species genome sequences, including Z bailii, was carried out using phylogenetic and gene neighbourhood approaches. Consistent with previous studies, this analysis revealed a group containing pre-whole genome duplication species Haa1/Cup2 single orthologues, including ZbHaa1, and two groups containing either Haa1 or Cup2 orthologues from post-whole genome duplication species. S. cerevisiae Cup2 (alias Ace1) is a transcription factor involved in response and tolerance to copper stress. Taken together, these observations led us to hypothesize and demonstrate that ZbHaa1 is also involved in copper-induced transcriptional regulation and copper tolerance. CONCLUSIONS: The transcription factor ZbHaa1 is required for adaptive response and tolerance to both acetic acid and copper stresses. The subfunctionalization of the single ancestral Haa1/Cup2 orthologue that originated Haa1 and Cup2 paralogues after whole genome duplication is proposed.

Yeasts found in vineyards and wineries.

Wine is a complex beverage, comprising thousands of metabolites that are produced through the action of a plethora of yeasts and bacteria during fermentation of grape must. These microbial communities originate in the vineyard and the winery and reflect the influence of several factors including grape variety, geographical location, climate, vineyard spraying, technological practices, processing stage and season (pre-harvest, harvest, post-harvest). Vineyard and winery microbial communities have the potential to participate during fermentation and influence wine flavour and aroma. Therefore, there is an enormous interest in isolating and characterising these communities, particularly non-Saccharomyces yeast species to increase wine flavour diversity, while also exploting regional signature microbial populations to enhance regionality. In this review we describe the role and relevance of the main non-Saccharomyces yeast species found in vineyards and wineries. This includes the latest reports covering the application of these species for winemaking; and the biotechnological characteristics and potential applications of non-Saccharomyces species in other areas. In particular, we focus attention on the species for which molecular and genomic tools and resources are available for study. Copyright © 2016 John Wiley & Sons, Ltd.

The spoilage yeast Zygosaccharomyces bailii: Foe or friend?

Zygosaccharomyces bailii is a non-Saccharomyces budding yeast known as one of the most aggressive food spoilage microorganisms, often isolated as a contaminant during wine fermentation, as well as from many acidic, high-sugar and canned foods. The spoilage ability relies on the yeast's unique feature of tolerating the most common preservatives such as sulphite, dimethyl dicarbonate, acetic acid and sorbic acid. Therefore, many studies have focused on the description of this peculiar tolerance with the aim of developing preventative measures against Z. bailii food spoilage. These studies demonstrated the involvement of diverse molecular and physiological mechanisms in the yeast resistance, comprising detoxification of preservatives, adaptation of the cytoplasmic pH and modulation of the cell wall/membrane composition. At the same time, the described traits unveiled Z. bailii as a novel potential workhorse for industrial bioprocesses. Here we present the yeast Z. bailii starting from important aspects of its robustness and concluding with the exploitation of its potential in biotechnology. Overall, the article describes Z. bailii from different perspectives, converging in presenting it as one of the most interesting species of the Saccharomycotina subphylum. Copyright © 2017 John Wiley & Sons, Ltd.

Genome sequence of the highly weak-acid-tolerant Zygosaccharomyces bailii IST302, amenable to genetic manipulations and physiological studies.

Zygosaccharomyces bailii is one of the most problematic spoilage yeast species found in the food and beverage industry particularly in acidic products, due to its exceptional resistance to weak acid stress. This article describes the annotation of the genome sequence of Z. bailii IST302, a strain recently proven to be amenable to genetic manipulations and physiological studies. The work was based on the annotated genomes of strain ISA1307, an interspecies hybrid between Z. bailii and a closely related species, and the Z. bailii reference strain CLIB 213T. The resulting genome sequence of Z. bailii IST302 is distributed through 105 scaffolds, comprising a total of 5142 genes and a size of 10.8 Mb. Contrasting with CLIB 213T, strain IST302 does not form cell aggregates, allowing its manipulation in the laboratory for genetic and physiological studies. Comparative cell cycle analysis with the haploid and diploid Saccharomyces cerevisiae strains BY4741 and BY4743, respectively, suggests that Z. bailii IST302 is haploid. This is an additional trait that makes this strain attractive for the functional analysis of non-essential genes envisaging the elucidation of mechanisms underlying its high tolerance to weak acid food preservatives, or the investigation and exploitation of the potential of this resilient yeast species as cell factory.

New yeasts-new brews: modern approaches to brewing yeast design and development.

The brewing industry is experiencing a period of change and experimentation largely driven by customer demand for product diversity. This has coincided with a greater appreciation of the role of yeast in determining the character of beer and the widespread availability of powerful tools for yeast research. Genome analysis in particular has helped clarify the processes leading to domestication of brewing yeast and has identified domestication signatures that may be exploited for further yeast development. The functional properties of non-conventional yeast (both Saccharomyces and non-Saccharomyces) are being assessed with a view to creating beers with new flavours as well as producing flavoursome non-alcoholic beers. The discovery of the psychrotolerant S. eubayanus has stimulated research on de novo S. cerevisiae × S. eubayanus hybrids for low-temperature lager brewing and has led to renewed interest in the functional importance of hybrid organisms and the mechanisms that determine hybrid genome function and stability. The greater diversity of yeast that can be applied in brewing, along with an improved understanding of yeasts' evolutionary history and biology, is expected to have a significant and direct impact on the brewing industry, with potential for improved brewing efficiency, product diversity and, above all, customer satisfaction.

Molecular basis for the recognition of methylated adenines in RNA by the eukaryotic YTH domain.

Methylation of the N6 position of selected internal adenines (m(6)A) in mRNAs and noncoding RNAs is widespread in eukaryotes, and the YTH domain in a collection of proteins recognizes this modification. We report the crystal structure of the splicing factor YT521-B homology (YTH) domain of Zygosaccharomyces rouxii MRB1 in complex with a heptaribonucleotide with an m(6)A residue in the center. The m(6)A modification is recognized by an aromatic cage, being sandwiched between a Trp and Tyr residue and with the methyl group pointed toward another Trp residue. Mutations of YTH domain residues in the RNA binding site can abolish the formation of the complex, confirming the structural observations. These residues are conserved in the human YTH proteins that also bind m(6)A RNA, suggesting a conserved mode of recognition. Overall, our structural and biochemical studies have defined the molecular basis for how the YTH domain functions as a reader of methylated adenines.

Two glycerol uptake systems contribute to the high osmotolerance of Zygosaccharomyces rouxii.

The accumulation of glycerol is essential for yeast viability upon hyperosmotic stress. Here we show that the osmotolerant yeast Zygosaccharomyces rouxii has two genes, ZrSTL1 and ZrSTL2, encoding transporters mediating the active uptake of glycerol in symport with protons, contributing to cell osmotolerance and intracellular pH homeostasis. The growth of mutants lacking one or both transporters is affected depending on the growth medium, carbon source, strain auxotrophies, osmotic conditions and the presence of external glycerol. These transporters are localised in the plasma membrane, they transport glycerol with similar kinetic parameters and besides their expected involvement in the cell survival of hyperosmotic stress, they surprisingly both contribute to an efficient survival of hypoosmotic shock and to the maintenance of intracellular pH homeostasis under non-stressed conditions. Unlike STL1 in Sa. cerevisiae, the two Z. rouxii STL genes are not repressed by glucose, but their expression and activity are downregulated by fructose and upregulated by non-fermentable carbon sources, with ZrSTL1 being more influenced than ZrSTL2. In summary, both transporters are highly important, though Z. rouxii CBS 732(T) cells do not use external glycerol as a source of carbon.

Sphingolipids contribute to acetic acid resistance in Zygosaccharomyces bailii.

Lignocellulosic raw material plays a crucial role in the development of sustainable processes for the production of fuels and chemicals. Weak acids such as acetic acid and formic acid are troublesome inhibitors restricting efficient microbial conversion of the biomass to desired products. To improve our understanding of weak acid inhibition and to identify engineering strategies to reduce acetic acid toxicity, the highly acetic-acid-tolerant yeast Zygosaccharomyces bailii was studied. The impact of acetic acid membrane permeability on acetic acid tolerance in Z. bailii was investigated with particular focus on how the previously demonstrated high sphingolipid content in the plasma membrane influences acetic acid tolerance and membrane permeability. Through molecular dynamics simulations, we concluded that membranes with a high content of sphingolipids are thicker and more dense, increasing the free energy barrier for the permeation of acetic acid through the membrane. Z. bailii cultured with the drug myriocin, known to decrease cellular sphingo-lipid levels, exhibited significant growth inhibition in the presence of acetic acid, while growth in medium without acetic acid was unaffected by the myriocin addition. Furthermore, following an acetic acid pulse, the intracellular pH decreased more in myriocin-treated cells than in control cells. This indicates a higher inflow rate of acetic acid and confirms that the reduction in growth of cells cultured with myriocin in the medium with acetic acid was due to an increase in membrane permeability, thereby demonstrating the importance of a high fraction of sphingolipids in the membrane of Z. bailii to facilitate acetic acid resistance; a property potentially transferable to desired production organisms suffering from weak acid stress.

[Metabolism of ethyl carbamate precursors in soy sauce by Zygosaccharomyces rouxii ZQ02Metabolism of ethyl carbamate precursors in soy sauce by Zygosaccharomyces rouxii ZQ02].

Objective: To study nitrogen metabolism of Zygosaccharomyces rouxii and its relationship with the formation of soy sauce ethyl carbamate precursors. Methods: Z. rouxii ZQ02 was cultivated with single source of nitrogen, preferred nitrogen sources or under salt stress, to investigate its ability of using arginine, citrulline and urea. Results: Alanine, glycine and asparaginate were confirmed to be the preferred nitrogen sources of Z. rouxii ZQ02. Addition of preferred nitrogen sources did not inhibit the use of urea and citrulline, on the contrary, the consumption of urea and citrulline by Z. rouxii ZQ02 was stimulated with the addition of alanine and glycine. Z. rouxii ZQ02 did not accumulate any citrulline and urea from degradation of arginine. Urea and citrulline were used by Z. rouxii ZQ02 in the medium with single source of nitrogen. However, use of citrulline and urea by Z. rouxii ZQ02 was strongly inhibited under saline stress, resulting in the incomplete use of ethyl carbamate precursors. Conclusion: Use of citrulline and urea by Z. rouxii ZQ02 was strongly inhibited under high salt stress, resulting in the accumulation of ethyl carbamate precursors produced by other microorganisms during soy sauce fermentation.

Zygosaccharomyces rouxii Trk1 is an efficient potassium transporter providing yeast cells with high lithium tolerance.

Zygosaccharomyces rouxii is an osmotolerant yeast growing in the presence of high concentrations of salts and/or sugars. The maintenance of intracellular potassium homeostasis is essential for osmostress adaptation. Zygosaccharomyces rouxii is endowed with only one typical potassium transporter (ZrTrk1). We characterized ZrTrk1 activity and its contribution to various physiological parameters in detail. Our results show that ZrTrk1 is a high-affinity K(+) transporting system efficiently discriminating between K(+) and Li(+) and indicate the presence of another, currently unknown K(+) importing system with a low affinity in Z. rouxii cells. Upon ZrTrk1 heterologous expression in Saccharomyces cerevisiae, it confers cells with a remarkably high lithium tolerance (even to wild-type strains) due to preventing Li(+) influx into cells, and is able to complement a plasma-membrane hyperpolarization and cell sensitivity to cationic compounds caused by the lack of endogenous K(+) transporters. Intracellular pH measurements with pHluorin, whose coding sequence was integrated into the genome, showed that the expression of ZrTrk1 also complements a decrease in intracellular pH in S. cerevisiae trk1Δ trk2Δ cells. Our data corroborate a tight connection between potassium and proton transporters in yeasts and provide new insights into Z. rouxii cation homeostasis and the basis of its high osmotolerance.

Both BAT1 and ARO8 are responsible for unpleasant odor generation in halo-tolerant yeast Zygosaccharomyces rouxii.

Soy sauce yeast Zygosaccharomyces rouxii plays a central role in the production of flavor compounds in soy sauce, while the flor-forming strain spoils its quality by producing 2-methylpropanoic acid, 2-methylbutanoic acid, and 3-methylbutanoic acid, which have an unpleasant odor. To investigate the relationship between flor formation and unpleasant odor, we measured the volatile compounds that accumulated under various growth conditions. As a result, marked amounts of 2-methylpropanoic acid, 2-methylbutanoic acid, or 3-methylbutanoic acid accumulated in synthetic medium containing valine, isoleucine, or leucine, respectively, under aerobic growth conditions. These results implied that the unpleasant compounds were produced from their corresponding branched chain amino acid (BCAA) when the cell was placed under aerobic condition through flor formation. The first step in BCAA catabolism and the last step in BCAA anabolism are both catalyzed by a BCAA transaminase. A mutant lacking the BCAA transaminase gene, BAT1, resulted in valine and isoleucine auxotrophy, while a mutant lacking both BAT1 and the α-aminoadipate aminotransferase gene, ARO8, resulted in valine, isoleucine, and leucine auxotrophy. Although the bat1∆ aro8∆ double mutant formed flor similarly to the wild-type strain, the mutant exhibited less unpleasant odor generation. These results suggest that the interconversion between 4-methyl-2-oxopentanoate and leucine is catalyzed by both Bat1p and Aro8p in Z. rouxii. Taken together, these results indicate that flor formation is not seemed to be directly linked to unpleasant odor generation. These findings encourage us to breed flor-forming yeasts without an unpleasant odor.

The high-capacity specific fructose facilitator ZrFfz1 is essential for the fructophilic behavior of Zygosaccharomyces rouxii CBS 732T.

Zygosaccharomyces rouxii is a fructophilic yeast that consumes fructose preferably to glucose. This behavior seems to be related to sugar uptake. In this study, we constructed Z. rouxii single-, double-, and triple-deletion mutants in the UL4 strain background (a ura3 strain derived from CBS 732(T)) by deleting the genes encoding the specific fructose facilitator Z. rouxii Ffz1 (ZrFfz1), the fructose/glucose facilitator ZrFfz2, and/or the fructose symporter ZrFsy1. We analyzed the effects on the growth phenotype, on kinetic parameters of fructose and glucose uptake, and on sugar consumption profiles. No growth phenotype was observed on fructose or glucose upon deletion of FFZ genes. Deletion of ZrFFZ1 drastically reduced fructose transport capacity, increased glucose transport capacity, and eliminated the fructophilic character, while deletion of ZrFFZ2 had almost no effect. The strain in which both FFZ genes were deleted presented even higher consumption of glucose than strain Zrffz1Δ, probably due to a reduced repressing effect of fructose. This study confirms the molecular basis of the Z. rouxii fructophilic character, demonstrating that ZrFfz1 is essential for Z. rouxii fructophilic behavior. The gene is a good candidate to improve the fructose fermentation performance of industrial Saccharomyces cerevisiae strains.

Enhanced D-arabitol production by Zygosaccharomyces rouxii JM-C46: isolation of strains and process of repeated-batch fermentation.

A new strain producing high yield of D-arabitol was isolated from hyperosmotic environments and the ITS rDNA sequencing analysis revealed it as Zygosaccharomyces rouxii. In addition, using a pH control and repeated-batch fermentation strategy in a 5-L reactor, the maximum yield and the highest volumetric productivity of D-arabitol were 93.48 ± 2.79 g/L and 1.143 g/L h, respectively. Volumetric productivity was successfully improved from 0.86 to 1.143 g/L h, which was increased by 32.9 % after 72 h of fermentation. Z. rouxii JM-C46 has potential to be used for D-arabitol and xylitol production from glucose via D-arabitol route.