Size of Cells and Physicochemical Properties of Membranes are Related to Flavor Production during Sake Brewing in the Yeast Saccharomyces cerevisiae

Yoda, Tsuyoshi; Saito, Tomoaki

doi:10.3390/membranes10120440

Cited by 12 publications

(62 citation statements)

References 36 publications

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“…The clearest morphological changes were detected during the breeding of K7GE41. The K7GE41 cells became obviously larger ( Figure 7 C), in good agreement with the observation that the sake yeast strain producing a sweet ginjo aroma was large [ 32 ]. In addition, K7GE41 exhibited morphological changes, such as an increased proportion of cells with delocalized actin patches, increased G2 cells, and nuclear localization in mother cells ( Figure 7 C).…”

Section: Resultssupporting

confidence: 87%

Genome Editing to Generate Sake Yeast Strains with Eight Mutations That Confer Excellent Brewing Characteristics

Chadani

Ohnuki

Isogai

et al. 2021

Cells

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Sake yeast is mostly diploid, so the introduction of recessive mutations to improve brewing characteristics requires considerable effort. To construct sake yeast with multiple excellent brewing characteristics, we used an evidence-based approach that exploits genome editing technology. Our breeding targeted the AWA1, CAR1, MDE1, and FAS2 genes. We introduced eight mutations into standard sake yeast to construct a non-foam-forming strain that makes sake without producing carcinogens or an unpleasant odor, while producing a sweet ginjo aroma. Small-scale fermentation tests showed that the desired sake could be brewed with our genome-edited strains. The existence of a few unexpected genetic perturbations introduced during breeding proved that genome editing technology is extremely effective for the serial breeding of sake yeast.

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Section: Resultssupporting

confidence: 87%

Genome Editing to Generate Sake Yeast Strains with Eight Mutations That Confer Excellent Brewing Characteristics

Chadani

Ohnuki

Isogai

et al. 2021

Cells

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“…Previously, our team had measured the concentration of such flavor molecules in sake . Therefore, the actual concentration was shown as an example of the concentration of such flavors that we reported previously; the actual concentration on the sake was 75, 16, and 100 μM for EC, IA, and IAA, respectively . This study is the first to report the dynamic shape changes induced by sake flavor molecules; 2 mM flavor solution was used with the same concentration and compared with glucose as the positive control solution.…”

Section: Resultsmentioning

confidence: 72%

“…The membrane properties are according to cell, organism, and membrane type . Studies of actual yeast cells reported that cell size differences corresponded to flavor production. ,, Morphological change of liposomes has received considerable attention recently, for example, the morphological change phase diagram is formed by the balance between the surface area and the encapsulation volume in the cell model. , It is well analyzed that the resulting excess surface area and deformation of liposomes due to osmotic pressure make the internal water escape to the surface to reduce the volume, increase the surface area of membrane lipids via isomerization, and so on. − Some studies have shown that membrane deformation occurs because the area of the membrane increases due to stimuli such as heat, and excess surface area is created while maintaining the internal volume. ,,, It has also been reported that liposome transformation is caused by a specific molecular interaction such as detergent , or polyphenol , with membrane lipid molecules. Recently, the impact of solvent selection on the microfluidic production of liposomes was reported .…”

Section: Resultsmentioning

confidence: 99%

“…Equal volumes of the lipid vesicle solution (6 μL) and flavor molecules or glucose solution (6 μL, 2 mM) were poured into a test tube and gently mixed by soft tapping. ,, The aforementioned mixed solution (6 μL) was placed in a silicon well (0.2 mm) in a glass slide and covered with a small coverslip . The changes in membrane morphology were observed using a phase-contrast microscope (Olympus BX-53, Japan) at RT …”

Section: Materials and Methodsmentioning

confidence: 99%

“…Dynamic shape changes by flavors such as EC, CA, IA, and IAA are attributed to the following reason. The reason is that the radius of flavor molecule-containing lipid vesicles is small in EC, CA, IA, and IAA, and these flavors change the fluidity of membranes. , Therefore, they may interact with membrane lipids and induce dynamic shape changes. This study investigated the dynamic shape changes of cell-sized liposomes induced by certain flavors for potential quality evaluation of drinks.…”

Section: Introductionmentioning

confidence: 99%

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Quality Evaluation of Drinks Based on Liposome Shape Changes Induced by Flavor Molecules

Yoda

2022

ACS Omega

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The flavors of ethyl caproate and isoamyl acetate and their precursors are crucial in sake brewing for fermentation and evaluation of the corresponding quality of drinks. However, the quality evaluation of drinks containing these flavors is challenging. Therefore, sake quality was evaluated via dynamic membrane transformation on cell-sized liposomes while adding flavor-containing solutions. Flavor varieties have been reported to influence dynamic shape change patterns. This study reports the observed difference in the dynamic shape change of each flavor. Based on these results, proper quality evaluation of drinks is expected.

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Phase‐Separated Structures of Sake Flavors‐Containing Cell Model Membranes

Yoda

2022

Chemistry & Biodiversity

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Sake (a traditional Japanese alcoholic beverage) contains ethyl caproate (EC), which enhances its economic value. Isovaleraldehyde (IVA) is also a well-known flavoring agent in alcoholic beverages, which some people enjoy. Recently, studies revealed that EC decreased the size of homogenous 1,2-Dioleoyl-sn-glycero-3phosphocholine (DOPC) liposomes whereas IVA increased their size. Cholesterol (Chol) and ergosterol were previously referred to as animal and fungus sterols. For the first time, this study demonstrated the phase behavior of the membrane in cell-sized liposomes containing EC and IVA. After adding EC, the solid ordered/ liquid disordered (Ld) and liquid ordered (Lo)/Ld phase separation in DOPC/dipalmitoyl-sn-glycero-3phosphocholine/cholesterol or ergosterol ternary membranes decreased, but the Lo/Ld phase separation decreased after adding IVA. Biophysics, physiological, and application aspects of EC and IVA evaluation were discussed. The findings of this study not only enhance our understanding of the function of flavors but also provide rapid and cost effective performance for the measurement.

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Size of Cells and Physicochemical Properties of Membranes are Related to Flavor Production during Sake Brewing in the Yeast Saccharomyces cerevisiae

Cited by 12 publications

References 36 publications

Genome Editing to Generate Sake Yeast Strains with Eight Mutations That Confer Excellent Brewing Characteristics

Genome Editing to Generate Sake Yeast Strains with Eight Mutations That Confer Excellent Brewing Characteristics

Quality Evaluation of Drinks Based on Liposome Shape Changes Induced by Flavor Molecules

Phase‐Separated Structures of Sake Flavors‐Containing Cell Model Membranes

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