The role of acetic acid bacteria in brewing and their detection in operation

Kubizniaková, Petra; Kyselová, Lucie; Brožová, Martina; Hanzalíková, Katarína; Matoulková, Dagmar

doi:10.18832/kp2021.67.511

Cited by 3 publications

(6 citation statements)

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“…Nowadays, for almost all beers produced the fermentation relies on specific yeast strains and the presence of bacteria is completely undesirable due to their spoilage potential ( Briggs et al, 2004 ; Vriesekoop et al, 2012 ). However, although their spoilage capacity, some specific beers do require LAB and/or AAB to introduce characteristic beer flavors ( Van Oevelen et al, 1977 ; De Keersmaecker, 1996 ; Tonsmeire, 2014 ; De Roos and De Vuyst, 2019 ; Bongaerts et al, 2021 ; Kubizniaková et al, 2021 ). Sour beers, with their typical refreshing and (slightly) acidic flavor because of high organic acid concentrations are an example of such beers, during the production process of some LAB or even both LAB and AAB are part of the core microbiota and hence contribute to their flavor formation ( Van Oevelen et al, 1976 ; Snauwaert et al, 2016 ; De Roos and De Vuyst, 2019 ; Bongaerts et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Acetic Acid Bacteria in Sour Beer Production: Friend or Foe?

Bouchez

Vuyst

2022

Front. Microbiol.

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Beer is the result of a multistep brewing process, including a fermentation step using in general one specific yeast strain. Bacterial presence during beer production (or presence in the beer itself) is considered as bad, since bacteria cause spoilage, produce off-flavors, and/or turbidity. Although most problems in the past related to lack of hygiene and/or cleaning, bacteria do still cause problems nowadays. Despite this negative imago, certain bacteria play an irreplaceable role during fermentation and/or maturation of more unique, funky, and especially refreshing sour beers. The term sour beers or sours is not restricted to one definition but covers a wide variety of beers produced via different techniques. This review proposes an uncluttered sour beer classification scheme, which includes all sour beer production techniques and pays special attention to the functional role of acetic acid bacteria. Whereas their oxidation of ethanol and lactate into acetic acid and acetoin usually spoils beer, including sour beers, organoleptically, a controlled growth leads to a desirable acidic flavor in sour beers, such as lambic-style, lambic-based, and red-brown acidic ales.

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Section: Introductionmentioning

confidence: 99%

Acetic Acid Bacteria in Sour Beer Production: Friend or Foe?

Bouchez

Vuyst

2022

Front. Microbiol.

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“…Acetic acid bacteria oxidize ethanol to acetic acid (Kubizniaková et al, 2021), and although aerobic, Gluconobacter species are ‘capable of developing at very low oxygen tensions’ (Ault, 1965). Whilst in the 1940s much feared in breweries, acetic acid bacteria are no longer a concern with closed vessels, packaging in kegs, significantly improved hygiene and oxygen stringently minimized to assure flavour stability of the product.…”

Section: Discussionmentioning

confidence: 99%

“…Whilst in the 1940s much feared in breweries, acetic acid bacteria are no longer a concern with closed vessels, packaging in kegs, significantly improved hygiene and oxygen stringently minimized to assure flavour stability of the product. However, the threat of acetic acid bacteria and associated vinegar taint in cask beer (Ault, 1965) remains a concern (Kubizniaková et al, 2021; Quain, 2015). Ingress of oxygen inevitably occurs during the dispense of cask beer and 46% of the microflora identified in cask ale samples were acetic acid bacteria.…”

Section: Discussionmentioning

confidence: 99%

“…Whilst presumably planktonic, micro‐organisms in dispensed keg lager, ale, stout and cask ale can form biofilms when incubated in microplates (Jevons & Quain, 2021). Indeed, many of the micro‐organisms in Table 2 have been identified in dispense biofilms including acetic acid bacteria (Kubizniaková et al, 2021; Thomas & Whitham, 1996), Lactobacillus species (Walker et al, 2007), Pediococcus (Heger & Russell, 2021; Thomas & Whitham, 1996) and Saccharomyces species (including S. diastaticus ) (Riedl, Fütterer, et al, 2019; Walker et al, 2007). Elsewhere biofilm formation has been reported for B. bruxellensis from beer in wine (Dimopoulou et al, 2019), R. mucilaginosa (Riedl, Fütterer, et al, 2019) in beer, some (but not all) 20 brewery isolates of L. brevis in beer (Riedl, Dünzer, et al, 2019) and five species of Lactobacillus in beer (Wang et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

“…and high in ethanol (4%–8% ABV) with a low pH (<4.2) and contains antimicrobial bitter substances derived from hops. Despite this, draught beer is susceptible to spoilage by a limited but diverse range of micro‐organisms (Quain, 2015), including aerotolerant gram‐positive bacteria ( Lactobacillus , Pediococcus ; Suzuki, 2015), aerobic Gram‐negative bacteria ( Acetobacter , Gluconobacter ; Kubizniaková et al, 2021), facultatively aerobic yeasts ( Saccharomyces ) and aerobic yeasts ( Brettanomyces , Pichia , Rhodotorula ; Powell & Kerruish, 2017).…”

Section: Introductionmentioning

confidence: 99%

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Identification of spoilage microflora in draught beer using culture-dependent methods

Jevons

Quain

2022

Journal of Applied Microbiology

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Aims: To determine whether the culture-dependent spoilage microflora found in draught beer are influenced by beer style.Methods and Results: Four beer styles-lager, ale, stout and cask ale -were sampled twice from five different public houses (accounts) in four different locations.The microbiological quality of the dispensed beers was determined by a culturedependent method ('forcing'), measuring the increase in turbidity after incubation at 30°C. The quality of draught beer varied from 'excellent' to 'poor' with cask beer samples having a higher Quality Index (90%) with keg ale the lowest (67.5%). With PCR amplified DNA (ITS1, ITS4, 16S rRNA primers) and blast identification of microflora, 386 colonies from agar plates were identified with 28 different microorganisms from five genera of yeast and six of bacteria. Seven micro-organisms were found in all beer styles with Brettanomyces bruxellensis, B. anomalus and Acetobacter fabarum representing 53% of the identified micro-organisms. A subsequent, limited study using PALL multiplex PCR GeneDisc technology on forced samples (without selection on plates) suggests that draught beer microflora is qualitatively broader. It is noteworthy that the microflora of spoilt draught beer resembles that involved in the production of Belgian Lambic sour beers.Conclusions: Draught beer was of variable quality. Culture-dependent analysis suggests that species of Brettanomyces and Acetobacter are core microflora with some micro-organisms being associated with beer style. Significance and Impact of the Study:The microbiological quality of draught beer is important both commercially and to the consumer. Here, we report the core and diverse microflora found in different styles of draught beer using culture-dependent methods. K E Y W O R D S beer spoilage, beer styles, draught beer, identification, microflora | 3729 MICROFLORA OF DRAUGHT BEER How to cite this article: Jevons, A.L. & Quain, D.E. (2022) Identification of spoilage microflora in draught beer using culture-dependent methods.

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Fermented foods, their microbiome and its potential in boosting human health

Valentino,

Magliulo,

Farsi

et al. 2024

Microbial Biotechnology

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Fermented foods (FFs) are part of the cultural heritage of several populations, and their production dates back 8000 years. Over the last ~150 years, the microbial consortia of many of the most widespread FFs have been characterised, leading in some instances to the standardisation of their production. Nevertheless, limited knowledge exists about the microbial communities of local and traditional FFs and their possible effects on human health. Recent findings suggest they might be a valuable source of novel probiotic strains, enriched in nutrients and highly sustainable for the environment. Despite the increasing number of observational studies and randomised controlled trials, it still remains unclear whether and how regular FF consumption is linked with health outcomes and enrichment of the gut microbiome in health‐associated species. This review aims to sum up the knowledge about traditional FFs and their associated microbiomes, outlining the role of fermentation with respect to boosting nutritional profiles and attempting to establish a link between FF consumption and health‐beneficial outcomes.

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The role of acetic acid bacteria in brewing and their detection in operation

Cited by 3 publications

References 47 publications

Acetic Acid Bacteria in Sour Beer Production: Friend or Foe?

Acetic Acid Bacteria in Sour Beer Production: Friend or Foe?

Identification of spoilage microflora in draught beer using culture-dependent methods

Fermented foods, their microbiome and its potential in boosting human health

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