Why some yeasts are better at fermentation in alcohol manufacturing

I will drink to that — PP2A^B55δ is the key molecule that makes sake yeast punch-drunk happy. Credit: Daisuke Watanabe

Alcohol has been celebrated throughout history. The ancient Greeks worshiped Dionysus, while the Chinese recognized Yidi as the creator of libertine drink. Unknowingly, both were actually servants of the true alcohol master, yeast. In Japan, some of the best sake is the result of a single mutation in yeast. Researchers at the Nara Institute of Science and Technology (NAIST) report in a new study published in Applied and Environmental Microbiology that the key molecule released from this mutation, PP2A^B55δ, allows yeast to ferment alcohol.

NAIST Assistant Professor Daisuke Watanabe and Professor Hiroshi Takagi have devoted their careers to studying yeast mutations to identify why some are better at fermentation than others. One example of this is the RIM15 gene in the sake yeast breed Kyokai number 7.

"RIM15 codes for RIM15p, and RIM15p inhibits alcohol fermentation. However, even after correcting the mutation, Kyokai number 7 can still ferment," says Watanabe.

This fact suggested to him that other molecules working with RIM15p are also involved in the fermentation. A deeper analysis revealed that Kyokai number 7 has two unusual molecular features besides the RIM15 mutation.

"We found high TORC1 activity," says Watanabe. TORC1 is known to inhibit RIM15p.

Ironically, fermentation causes stress on yeast, which can cause the cells to die. To conserve energy, yeast stop growing, which includes lowering fermentation activity. "This elevated TORC1 activity seems novel to sake yeast cells," Watanabe says.

Where TORC1 is a molecule that suppresses RIM15p, the second factor is a molecule released by RIM15p inhibition.

"CDC55 encodes ^B55δ, a regulatory subunit, on PP2A [PP2A^B55δ]. Mutating this gene resulted in yeast that could no longer ferment alcohol," notes Watanabe. This was true even when RIM15p was inhibited, suggesting that PP2A^B55δ is a major regulator of alcohol fermentation by yeast.

By understanding all the molecules involved in alcohol fermentation and how they interact with each other, Watanabe is optimistic that it will be possible to improve fermentation by targeting individual steps in the process.

"We hypothesize that the high TORC1 activity and the loss of RIM15p contribute to the activation of PP2A^B55δ. This finding suggests a critical molecular pathway for alcohol fermentation by yeast. By studying the individual steps, we can identify ways to chemically enhance production," he says.

Explore further: 'Hoppy' beer without exploding bottles and too much alcohol

More information: Daisuke Watanabe et al, Nutrient Signaling via the TORC1-Greatwall-PP2AB55δ Pathway Responsible for the High Initial Rates of Alcoholic Fermentation in Sake Yeast Strains of Saccharomyces cerevisiae, Applied and Environmental Microbiology (2018). DOI: 10.1128/AEM.02083-18

	Why some yeasts are better at fermentation in alcohol manufacturing
	admin
	2018-10-29
发布年	2018
语种	英语
国家	美国
领域	地球科学
正文(英文)	PP2A^B55δ is the key molecule that makes sake yeast punch-drunk happy. Credit: Daisuke Watanabe Alcohol has been celebrated throughout history. The ancient Greeks worshiped Dionysus, while the Chinese recognized Yidi as the creator of libertine drink. Unknowingly, both were actually servants of the true alcohol master, yeast. In Japan, some of the best sake is the result of a single mutation in yeast. Researchers at the Nara Institute of Science and Technology (NAIST) report in a new study published in Applied and Environmental Microbiology that the key molecule released from this mutation, PP2A^B55δ, allows yeast to ferment alcohol. NAIST Assistant Professor Daisuke Watanabe and Professor Hiroshi Takagi have devoted their careers to studying yeast mutations to identify why some are better at fermentation than others. One example of this is the RIM15 gene in the sake yeast breed Kyokai number 7. "RIM15 codes for RIM15p, and RIM15p inhibits alcohol fermentation. However, even after correcting the mutation, Kyokai number 7 can still ferment," says Watanabe. This fact suggested to him that other molecules working with RIM15p are also involved in the fermentation. A deeper analysis revealed that Kyokai number 7 has two unusual molecular features besides the RIM15 mutation. "We found high TORC1 activity," says Watanabe. TORC1 is known to inhibit RIM15p. Ironically, fermentation causes stress on yeast, which can cause the cells to die. To conserve energy, yeast stop growing, which includes lowering fermentation activity. "This elevated TORC1 activity seems novel to sake yeast cells," Watanabe says. Where TORC1 is a molecule that suppresses RIM15p, the second factor is a molecule released by RIM15p inhibition. "CDC55 encodes ^B55δ, a regulatory subunit, on PP2A [PP2A^B55δ]. Mutating this gene resulted in yeast that could no longer ferment alcohol," notes Watanabe. This was true even when RIM15p was inhibited, suggesting that PP2A^B55δ is a major regulator of alcohol fermentation by yeast. By understanding all the molecules involved in alcohol fermentation and how they interact with each other, Watanabe is optimistic that it will be possible to improve fermentation by targeting individual steps in the process. "We hypothesize that the high TORC1 activity and the loss of RIM15p contribute to the activation of PP2A^B55δ. This finding suggests a critical molecular pathway for alcohol fermentation by yeast. By studying the individual steps, we can identify ways to chemically enhance production," he says. Explore further: 'Hoppy' beer without exploding bottles and too much alcohol More information: Daisuke Watanabe et al, Nutrient Signaling via the TORC1-Greatwall-PP2AB55δ Pathway Responsible for the High Initial Rates of Alcoholic Fermentation in Sake Yeast Strains of Saccharomyces cerevisiae, Applied and Environmental Microbiology (2018). DOI: 10.1128/AEM.02083-18
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来源平台	Science X network
文献类型	新闻
条目标识符	http://119.78.100.173/C666/handle/2XK7JSWQ/125319
专题	地球科学
推荐引用方式 GB/T 7714	admin. Why some yeasts are better at fermentation in alcohol manufacturing. 2018.

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