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1. Growing microbiology literacy through interdisciplinary approaches to food fermentations and an Indigenous peoples’ rights framework

   https://doi.org/10.1128/jmbe.00152-24  

   Hauptmann, Aviaja Lyberth; Maroney, Stephanie; Bissett_Perea, Jessica; Marco, Maria L (January 2025, Journal of Microbiology & Biology Education)

   Pandey, Sumali (Ed.)

   ABSTRACT New approaches to microbiology education are needed to ensure equitable representation in microbiology and to build literacy in microbiology and science broadly. To address this goal, we developed a course held at the collegiate level that uniquely integrated microbiology, Indigenous studies, science and technology studies, and arts and performance. The course participants included students in 12 majors across science, engineering, humanities, and arts. The different disciplines of the course intersected around Inuit fermented foods as the basis for discussions on fundamental microbiological principles, the scientific method, food sovereignty, and Indigenous peoples’ rights. A diverse array of activities was included, ranging from lectures in microbiology and fermentation, a sauerkraut-making lab, a walk through the Native American contemplative garden, a workshop on Inuit drum making and dance, as well as a performance by Inuit-soul group Pamyua. We propose that a radically interdisciplinary approach and a human rights framework in microbiology education can be a way to enhance microbiology and science literacy for a diverse group of students. 

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2. Inhibition of diastatic yeasts by Saccharomyces killer toxins to prevent hyperattenuation during brewing

   https://doi.org/10.1128/aem.01072-24  

   Zhong, Victor; Ketchum, Nicholas; Mackenzie, James K; Garcia, Ximena; Rowley, Paul A (October 2024, Applied and Environmental Microbiology)

   Dudley, Edward G (Ed.)

   ABSTRACT Secondary fermentation in beer can result in undesirable consequences, such as off-flavors, increased alcohol content, hyperattenuation, gushing, and the spontaneous explosion of packaging. Strains ofSaccharomyces cerevisiae var. diastaticusare a major contributor to such spoilage due to their production of extracellular glucoamylase enzyme encoded by theSTA1gene.Saccharomycesyeasts can naturally produce antifungal proteins named “killer” toxins that inhibit the growth of competing yeasts. Challenging diastatic yeasts with killer toxins revealed that 91% of strains are susceptible to the K1 killer toxin produced byS. cerevisiae. Screening of 192 killer yeasts identified novel K2 toxins that could inhibit all K1-resistant diastatic yeasts. Variant K2 killer toxins were more potent than the K1 and K2 toxins, inhibiting 95% of diastatic yeast strains tested. Brewing trials demonstrated that adding killer yeast during a simulated diastatic contamination event could prevent hyperattenuation. Currently, most craft breweries can only safeguard against diastatic yeast contamination by good hygiene and monitoring for the presence of diastatic yeasts. The detection of diastatic yeasts will often lead to the destruction of contaminated products and the aggressive decontamination of brewing facilities. Using killer yeasts in brewing offers an approach to safeguard against product loss and potentially remediate contaminated beer.IMPORTANCEThe rise of craft brewing means that more domestic beer in the marketplace is being produced in facilities lacking the means for pasteurization, which increases the risk of microbial spoilage. The most damaging spoilage yeasts are “diastatic” strains ofSaccharomyces cerevisiaethat cause increased fermentation (hyperattenuation), resulting in unpalatable flavors such as phenolic off-flavor, as well as over-carbonation that can cause exploding packaging. In the absence of a pasteurizer, there are no methods available that would avert the loss of beer due to contamination by diastatic yeasts. This manuscript has found that diastatic yeasts are sensitive to antifungal proteins named “killer toxins” produced bySaccharomycesyeasts, and in industrial-scale fermentation trials, killer yeasts can remediate diastatic yeast contamination. Using killer toxins to prevent diastatic contamination is a unique and innovative approach that could prevent lost revenue to yeast spoilage and save many breweries the time and cost of purchasing and installing a pasteurizer. 

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3. A hypothesis-based hop microbiology laboratory module testing the plausibility of the mythical origin of the India Pale Ale

   https://doi.org/10.1128/jmbe.00020-24  

   Molina-Pineda, Julio; Scholes, Amanda N; Lewis, Jeffrey A (April 2024, Journal of Microbiology & Biology Education)

   Westenberg, Dave J (Ed.)

   As one of the most famous fermented drinks in the world, beer is an especially relatable topic for microbiology courses. Here, we describe a short and easily adaptable module based on the antibacterial properties of hops used in brewing. By the 15th century, beer recipes included hops (the flower of the Humulus lupulusplant) as a bittering agent and antimicrobial. By the 19th century, the highly hopped Indian Pale Ale (IPA) became popular, and a modern myth has emerged that IPAs were invented to survive long ocean voyages such as from Britain to India. With that myth in mind, we designed a hypothesis-driven microbiology lab module that tests the plausibility of this brewing myth—namely that highly hopped beers possess enough antibacterial activity to prevent spoilage, while lowly hopped beers do not. The overall design of the module is to test the antimicrobial properties of hops using petri plates containing varying concentrations of hop extract. The module includes hypothesis generation and testing related to bacterial physiology and cell envelope morphology (hops are not equally effective against Gram-positive and Gram-negative bacteria) and to mechanisms of antimicrobial resistance (as beer spoilage bacteria have repeatedly evolved hop resistance). Pre- and post-assessment showed that students made significant gains in the learning objectives for the module, which encourages critical thinking and hypothesis testing by linking microbial physiology and antimicrobial resistance to an important and topical real-world application. 

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4. Novel fermentations integrate traditional practice and rational design of fermented-food microbiomes

   https://doi.org/10.1016/j.cub.2024.09.047  

   Arrigan, Dillon; Kothe, Caroline Isabel; Oliverio, Angela; Evans, Joshua D; Wolfe, Benjamin E (November 2024, Current Biology)

   Fermented foods and beverages have been produced around the world for millennia, providing humans with a range of gastronomic, cultural, health, and scientific benefits. Building on these traditional forms, a conver- gence of factors, including culinary innovation, globalization, shifts in consumer preferences, and advances in microbiome sciences, has led to the emergence of so-called ‘novel fermentations’. In this review, we define novel fermentation as the confluence of traditional food practices and rational microbiome design. Using principles of microbial ecology and evolution, we develop a microbiological framework that outlines several strategies for producing and characterizing novel fermentations, including switching substrates, engrafting target species, assembling whole-community chimeras, and generating novel phenotypes. A subsequent analysis of existing traditional ferments points to gaps in ‘fermentation space’ where novel ferments could potentially be produced using new combinations of microbes and food substrates. We highlight some impor- tant safety and sociocultural issues presented by the repurposing and modification of microbes from tradi- tional ferments that fermented-food producers and microbiologists need to address. 

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5. Population Genomics of Aspergillus sojae is Shaped by the Food Environment

   https://doi.org/10.1093/gbe/evaf067  

   Acevedo, Kimberly L; Eaton, Elizabeth; Leite, Julia; Zhao, Shu; Chacon-Vargas, Katherine; McCarthy, Colin M; Choi, Dasol; O’Donnell, Samuel; Gluck-Thaler, Emile; Yu, Jae-Hyuk; et al (April 2025, Genome Biology and Evolution)

   Zufall, Rebecca (Ed.)

   Abstract Traditional fermented foods often contain specialized microorganisms adapted to their unique environments. For example, the filamentous mold Aspergillus oryzae, used in saké fermentation, has evolved to thrive in starch-rich conditions compared to its wild ancestor, Aspergillus flavus. Similarly, Aspergillus sojae, used in soybean-based fermentations like miso and shochu, is hypothesized to have been domesticated from Aspergillus parasiticus. Here, we examined the effects of long-term A. sojae use in soybean fermentation on population structure, genome variation, and phenotypic traits. We analyzed 17 A. sojae and 24 A. parasiticus genomes (23 of which were sequenced for this study), alongside phenotypic traits of 9 isolates. Aspergillus sojae formed a distinct, low-diversity population, suggesting a recent clonal expansion. Interestingly, a population of A. parasiticus was more closely related to A. sojae than other A. parasiticus populations. Genome comparisons revealed loss-of-function mutations in A. sojae, notably in biosynthetic gene clusters encoding secondary metabolites, including the aflatoxin cluster. Interestingly though, A. sojae harbored a partial duplication of a siderophore biosynthetic cluster. Phenotypic assays showed A. sojae lacked aflatoxin production, while it was variable in A. parasiticus isolates. Additionally, certain A. sojae strains exhibited larger colony diameters under miso-like salt conditions. These findings support the hypothesis that A. parasiticus is the progenitor of A. sojae and that domestication significantly reduced genetic diversity. Future research should explore how wild and food-associated strains influence sensory attributes and microbial community dynamics in fermented soy products. 

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