Indigenous Bacteria and Fungi Drive Traditional Kimoto Sake Fermentations

Bokulich, Nicholas A.; Ohta, Moe; Lee, Morgan; Mills, David A.

doi:10.1128/aem.00663-14

Cited by 94 publications

(57 citation statements)

References 41 publications

(61 reference statements)

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“…Successive molecular characterization of the evolving microbiome over the course of lambic fermentations have identified qualitatively distinct, semi-overlapping phases dominated at first by a variety of enterobacteria and non- Saccharomyces yeasts followed by increasing levels of Saccharomyces including S. cerevisiae and S. bayanus [74,75], then LAB, and finally by Brettanomyces bruxellensis [75,76]. Similar microbial communities and progressions have been documented in other types of spontaneously fermented beer [28,77] and in traditionally produced kimoto-style sake [78]. Again, while no overt inoculation of microbes occurs during the production of these beverages, there are nonetheless microbes resident to the brew house environment which take part in the fermentation process and show signatures of adaptation [28,77] [79].…”

Section: Microbial Community Dynamics Of Fermented Foodmentioning

confidence: 87%

The genomics of microbial domestication in the fermented food environment

Gibbons

Rinker

2015

Current Opinion in Genetics & Development

116

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Shortly after the agricultural revolution, the domestication of bacteria, yeasts, and molds, played an essential role in enhancing the stability, quality, flavor, and texture of food products. These domestication events were likely the result of human food production practices that entailed the continual recycling of isolated microbial communities in the presence of abundant agricultural food sources. We suggest that within these novel agrarian food niches the metabolic requirements of those microbes became regular and predictable resulting in rapid genomic specialization through such mechanisms as pseudogenization, genome decay, interspecific hybridization, gene duplication, and horizontal gene transfer. The ultimate result was domesticated strains of microorganisms with enhanced fermentative capacities.

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Section: Microbial Community Dynamics Of Fermented Foodmentioning

confidence: 87%

The genomics of microbial domestication in the fermented food environment

Gibbons

Rinker

2015

Current Opinion in Genetics & Development

116

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“…In other studies, the microbiota was related to raw material origin (Bokulich et al ., 2014a; Rizzello et al ., 2015) or quality (Dolci et al ., 2014; O'Sullivan et al ., 2015; Alessandria et al ., 2016), as well as to development of flavour‐impact compounds (De Pasquale et al ., 2014a, 2016; De Filippis et al ., 2016a). Moreover, food‐related environments were found to harbour a resident microbiota, beneficially involved in dairy (Bokulich and Mills, 2013a; Stellato et al ., 2015; Calasso et al ., 2016), alcoholic (Bokulich et al ., 2012a, 2014b) and sourdough (Minervini et al ., 2015) fermentations, although the presence of potential spoilers was also emphasized in some cases (Bokulich et al ., 2015a; Stellato et al ., 2015). …”

Section: Monitoring Microbes In Food Fermentationsmentioning

confidence: 99%

Metagenomics insights into food fermentations

Filippis

Parente

2016

Microbial Biotechnology

202

117

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SummaryThis review describes the recent advances in the study of food microbial ecology, with a focus on food fermentations. High‐throughput sequencing (HTS) technologies have been widely applied to the study of food microbial consortia and the different applications of HTS technologies were exploited in order to monitor microbial dynamics in food fermentative processes. Phylobiomics was the most explored application in the past decade. Metagenomics and metatranscriptomics, although still underexploited, promise to uncover the functionality of complex microbial consortia. The new knowledge acquired will help to understand how to make a profitable use of microbial genetic resources and modulate key activities of beneficial microbes in order to ensure process efficiency, product quality and safety.

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“…Thus, high-throughput sequencing technologies are providing the greatest advance to this sector of research, where the increased sample throughput and detection sensitivity support analysis of larger and more complex studies. Amplicon sequencing approaches have been applied to study the microbial ecology of pearl millet fermentations [6], various Asian vegetable fermentations [7–9], seafood fermentations [10], Chinese liquor [11], cheese [12–14], sake [15] and other rice beers [16], olives [17], sourdough [18], kombucha [19], kefir and similar fermentations [20,21], wine [22,23], and spontaneously fermented American coolship ale fermentations [24,25]. What types of questions can be answered from describing the microbial succession in these fermented foods?…”

Section: Application Of Microbial System-level Tools In Food Productionmentioning

confidence: 99%

“…coolship beers) [24], and/or multiple stages with mixed consortia (e.g. rice wine fermentations) [15,16]. Describing the normal and abnormal microbial states at different stages of these fermentations is important to characterizing consistency, identifying biomarkers for product quality or spoilage, diagnosing problem fermentations, and learning to manipulate fermentation conditions for improved process control.…”

Section: Application Of Microbial System-level Tools In Food Productionmentioning

confidence: 99%

“…The aging-room surfaces of different cheesemaking plants harbor distinct, indigenous microbial communities that dominate the surfaces of the cheeses aged therein, forming the basis for a ‘house’ microbiome involved in regional cheesemaking [51]. We see a similar situation in a kimoto (uninoculated) sake brewery, where the bacteria and yeast conducting these fermentations are vectored on equipment surfaces [15]. In beer breweries, season, substrate, and human processes all shape the microbial communities of equipment surfaces [52 •• ].…”

Section: Food Building Ecosystemsmentioning

confidence: 99%

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A new perspective on microbial landscapes within food production

Bokulich

Lewis

Boundy‐Mills

et al. 2016

Current Opinion in Biotechnology

107

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High-throughput, ‘next-generation’ sequencing tools offer many exciting new possibilities for food research. From investigating microbial dynamics within food fermentations to the ecosystem of the food-processing built environment, amplicon sequencing, metagenomics, and transcriptomics present novel applications for exploring microbial communities in, on, and around our foods. This review discusses the many uses of these tools for food-related and food facility-related research and highlights where they may yield nuanced insight into the microbial world of food production systems.

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Indigenous Bacteria and Fungi Drive Traditional Kimoto Sake Fermentations

Cited by 94 publications

References 41 publications

The genomics of microbial domestication in the fermented food environment

The genomics of microbial domestication in the fermented food environment

Metagenomics insights into food fermentations

A new perspective on microbial landscapes within food production

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