Tomato root-associated Sphingobium harbors genes for catabolizing toxic steroidal glycoalkaloids.

IMPORTANCE: Saponins are a group of plant specialized metabolites with various bioactive properties, both for human health and soil microorganisms. Our previous works demonstrated that Sphingobium is enriched in both soils treated with a steroid-type saponin, such as tomatine, and in the tomato rhizosphere. Despite the importance of saponins in plant-microbe interactions in the rhizosphere, the genes involved in the catabolism of saponins and their aglycones (sapogenins) remain largely unknown. Here we identified several enzymes that catalyzed the degradation of steroid-type saponins in a Sphingobium isolate from tomato roots, RC1. A comparative genomic analysis of Sphingobium revealed the limited distribution of genes for saponin degradation in our saponin-degrading isolates and several other isolates, suggesting the possible involvement of the saponin degradation pathway in the root colonization of Sphingobium spp. The genes that participate in the catabolism of sapogenins could be applied to the development of new industrially valuable sapogenin molecules.

Generation of new hybrids by crossbreeding between bottom-fermenting yeast strains.

The genetic diversity of bottom-fermenting yeast classified as Saccharomyces pastorianus is poor because strains are restricted to a few genetically distinct groups. Crossbreeding is an effective approach to construct novel yeast strains, but it is difficult because of inefficiency to obtain mating-competent cells (MCCs) of bottom-fermenting yeast. By using mating pheromone-supersensitive mutants, we previously isolated several mating-competent meiotic segregants from two bottom-fermenting yeast strains: high isoamyl acetate-producing KY1247, and low diacetyl-producing KY2645. Here, we constructed novel non-GM hybrids carrying preferable characteristics from both parents by crossbreeding these bottom-fermenting strains for the first time. Sixteen a/a-type meiotic segregants from KY2645 and 12 α/α-type meiotic segregants from KY1247 were mixed, and cells resembling zygotes were isolated via micromanipulation. In total, 149 hybrids were obtained and verified by examining known single-nucleotide polymorphisms (SNPs) between the parental strains. A sporulation test showed that some of the hybrids were able to sporulate. Moreover, fermentation tests on a test-tube and pilot-plant scale identified two hybrids with production levels of isoamyl acetate and diacetyl that were almost the same as KY1247 and KY2645, respectively. Both of these hybrids produced satisfactory beer in terms of taste, flavor, and overall quality, comparable to that produced by the parental strains. Collectively, our results suggest that crossbreeding between bottom-fermenting yeast strains has the potential to increase the diversity of yeast strains available for brewing, and our method of isolating MCCs provides a huge advance for crossbreeding of bottom-fermenting yeast without using DNA recombination techniques.

An efficient method for isolating mating-competent cells from bottom-fermenting yeast using mating pheromone-supersensitive mutants.

Crossbreeding is an effective approach to construct novel yeast strains with preferred characteristics; however, it is difficult to crossbreed strains of brewer's yeast, especially the bottom-fermenting yeast Saccharomyces pastorianus, because of the relative inefficiency of the available methods to obtain mating-competent cells (MCCs). Here, we describe a productive method for the isolation of MCCs without artificial genetic modification. We focused on the characteristics of two mating pheromone-supersensitive mutants, Δbar1 and Δsst2, that show a growth defect in the presence of the mating pheromone. When MCCs secreting α-factor and a-factor were spotted on to a lawn of MATa Δbar1 and MATα Δsst2, a halo was observed around the respective MCCs. This plate assay was successful in identifying MCCs from bottom-fermenting yeast strains. Furthermore, by selecting for cells that caused the growth defect in pheromone-supersensitive cells on cultures plates, 40 α/α-type and six a/a-type meiotic segregants of bottom-fermenting yeast strains were successfully isolated and crossed with tester strains to verify their mating type. This method of isolation is expected to be applicable to other industrial yeast strains, including wine, sake and distiller's yeasts, and will enable MCCs without genetic modifications to be obtained. As a result, it will be a useful tool for more convenient and efficient crossbreeding of industrial yeast strains that can be applied to practical brewing. Copyright © 2017 John Wiley & Sons, Ltd.

Intracellular proteins of ethanol-treated yeast cells involved in iron sorption.

Iron is essential for human health, but it sometimes causes an unpleasant taste, rusty colour and a decrease in the stability of food products. Previously, we found that ethanol-treated yeast (ETY) cells could remove iron from wine and juice, and reduce the fishy aftertaste induced by iron in wine-seafood pairings. However, the mechanism of iron sorption by ETY cells is undefined; thus, there is no indicator that can be used to estimate the iron sorption capacity of these cells. In this study, we showed that cell wall components are not mainly associated with iron sorption by investigating ETY cells with the cell wall removed. Moreover, plasma membrane permeability was correlated with the iron sorbing capacity of the cells. Microscopic analysis showed that iron accumulated within ETY cells. Proteinase-treated ETY cells had no iron sorbing capacity. On the basis of these results, we conclude that intracellular proteins are involved in iron sorption by ETY cells.

Novel method to reduce fishy aftertaste in wine and seafood pairing using alcohol-treated yeast cells.

"Fishy aftertaste" is sometimes perceived in wine consumed with seafood. Iron in wine has been reported to be a key compound that produces fishy aftertaste. However, cost-effective methods to remove iron from wine have not been developed. Here, we describe a cost-effective and safe iron adsorbent consisting of alcohol-treated yeast (ATY) cells based on the observation that nonviable cells adsorbed iron after completion of fermentation. Treatment of cells with more than 40% (v/v) ethanol killed them without compromising their ability to adsorb iron. Drying the ATY cells did not reduce iron adsorption. Use of ATY cells together with phytic acid had a synergistic effect on iron removal. We term this means of removing iron the "ATY-PA" method. Sensory analysis indicated that fishy aftertaste in wine-seafood pairings was not perceived if the wine had been pretreated with both ATY cells and phytic acid.

Multi-locus genotyping of bottom fermenting yeasts by single nucleotide polymorphisms indicative of brewing characteristics.

Yeast plays a capital role in brewing fermentation and has a direct impact on flavor and aroma. For the evaluation of competent brewing strains during quality control or development of novel strains it is standard practice to perform fermentation tests, which are costly and time-consuming. Here, we have categorized DNA markers which enable to distinguish and to screen brewing strains more efficiently than ever before. Sequence analysis at 289 loci in the genomes of six bottom fermenting Saccharomyces pastorianus strains revealed that 30 loci contained single nucleotide polymorphisms (SNPs). By determining the nucleotide sequences at the SNP-loci in 26 other S. pastorianus strains and 20 strains of the top fermenting yeast Saccharomyces cerevisiae, almost all these strains could be discriminated solely on the basis of the SNPs. By comparing the fermentative phenotypes of these strains we found that some DNA markers showed a strong association with brewing characteristics, such as the production of ethyl acetate and hydrogen sulphide (H2S). Therefore, the DNA markers we identified will facilitate quality control and the efficient development of brewing yeast strains.

Identification and characterization of amidase- homologous AMI1 genes of bottom-fermenting yeast.

It has been proposed that a bottom-fermenting yeast strain of Saccharomyces pastorianus is a natural hybrid between S. cerevisiae and S. bayanus and possesses at least two types of genome. In the process of conducting expressed sequence tag (EST) analysis, we isolated bottom-fermenting yeast-specific (BFY) genes that have no significant homology with sequences in the S288C database. One of the BFY genes, AMI1, encodes a protein with homology to an amidase conserved among plants, Bacillus subtilis, Neurospora crassa, Schizosaccharomyces pombe and Saccharomyces species, with the exception of S. cerevisiae S288C. In the bottom-fermenting yeast, three alleles of AMI1 (one AMI1-A and two AMI1-B alleles) were found on different chromosomes. AMI1-A on chromosome XIII is most homologous to the S. bayanus AMI1 gene, while AMI1-B on chromosome X is most homologous to the Saccharomyces paradoxus AMI1 gene. Overproduction of AMI1 in S. cerevisiae resulted in a slow-growth phenotype. Although a hydropathy plot shows that Ami1p has a putative signal sequence, it was located in the cell, not secreted into the medium. By metabolome analysis of intracellular compounds, the amount of histidine and arginine is increased, and the amount of threonine, lysine and nicotinic acid is decreased in the Ami1p-overproducing strain as compared with the control, suggesting that Ami1p may hydrolyse some amides related to amino acid and niacin metabolism in the cell.

A structural and phylogenetic study of the HO gene from Saccharomyces bayanus var. uvarum.

A novel HO gene (Uv-HO) was cloned from the Saccharomyces bayanus var. uvarum (abbreviated as S. uvarum in this study) type strain. The coding region of Uv-HO showed relatively high homology (95%) to that of the Sb-HO gene (S. bayanus var. bayanus HO), but not to the HO genes of other Saccharomyces sensu stricto species. However, the 5' and 3' non-coding region of Uv-HO showed less similarity (79% and 76% respectively) even to those of the most homologous gene Sb-HO. Motifs of the mating-type control and the cell-cycle control were conserved in the 5' non-coding region of Uv-HO, but numbers and positions of motifs were different from those of Sb-HO. CHEF-Southern analysis showed that all tested strains of S. bayanus species, including S. uvarum, carried the HO gene on the 1,100-kb chromosome. By HO-typing PCR using mixed primers, which provided a rapid and convenient tool for yeast identification, either the Uv-HO gene or the Sb-HO gene was detected in strains of S. bayanus species, but two strains were found to have both types of HO gene in each genome. These results suggest that S. uvarum has a unique sequence, but might share the same chromosome constitution within S. bayanus species, and that S. bayanus is a heterogeneous species, of which some strains might be natural hybrid.

Preparation of artificially spiked soil with polycyclic aromatic hydrocarbons for soil pollution analysis.

To confirm the method for preparing artificially spiked soil with polycyclic aromatic hydrocarbons (PAHs), we tested the homogeneity of PAHs in spiked soils, which were prepared by three different procedures, by using kaolin and ando soil. When the slurry of kaolin and acetone containing PAHs were evaporated by a rotary evaporator at 30 - 35 degrees C, the most homogeneous distribution of PAHs was obtained in the spiked soil. This procedure was applied to the preparation of PAH-spiked soil for natural soil (ando soil). Such spiked soils can be useful as the standard materials for standardization of the analytical methods for PAHs in the soil and sediment samples.