Lifestyle, metabolism and environmental adaptation in<i>Lactococcus lactis</i>

Kleerebezem, Michiel; Bachmann, Herwig; Pelt-KleinJan, Eunice van; Douwenga, Sieze; Smid, Eddy J.; Teusink, Bas; Mastrigt, Oscar van

doi:10.1093/femsre/fuaa033

Cited by 43 publications

(27 citation statements)

References 168 publications

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“…Resident microbes have evolved a variety of strategies to maintain proliferative capacity under nutrient‐poor conditions for long periods (Egli, 2010; Hoehler and Jorgensen, 2013; Hallsworth, 2021). They adapt to such conditions by minimizing their energy expenditure and metabolic activity, ultimately resulting in a slow‐ or non‐growing state (Lennon and Jones, 2011; Boutte and Crosson, 2013; Ercan et al ., 2013; Hoehler and Jorgensen, 2013; Kleerebezem et al ., 2020). Distinct non‐growing phenotypes have been described, including spores, akinetes, biofilms and viable but non‐culturable states (Harrison et al ., 2007; Navarro Llorens et al ., 2010; Lennon and Jones, 2011; Boutte and Crosson, 2013; van Mastrigt et al ., 2018; van Tatenhove‐Pel et al ., 2019).…”

Section: Figmentioning

confidence: 99%

The growth‐survival trade‐off is hard‐wired in the Lactococcus lactis gene regulation network

Ercan

Besten

Smid

et al. 2022

Environ Microbiol Rep

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Most microbes reside in oligotrophic environments for extended periods of time, requiring survival strategies that maintain proliferative capacity. We demonstrate that the non-spore-forming Lactococcus lactis KF147 progressively activates the expression of stress-associated functions in response to the declining growth rate elicited by prolonged retentostat cultivation, which coincides with up to 10 4 -fold increased stress tolerance. Our findings provide a quantified view of the transcription and stresstolerance adaptations underlying the growth-survival trade-off in L. lactis, and exemplify the hard-wiring of this trade-off in the lactococcal gene regulation network.

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Section: Figmentioning

confidence: 99%

The growth‐survival trade‐off is hard‐wired in the Lactococcus lactis gene regulation network

Ercan

Besten

Smid

et al. 2022

Environ Microbiol Rep

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“…Lactic acid bacteria also significantly add to the flavor and texture profiles of the fermentation end-products resulting from animal milk and plant-based substrates. Moreover, the acidification capacity of these bacteria can inhibit pathogenic growth, typically resulting in longer shelf life ( 20 ). In addition to the ability of the lactobacilli to produce riboflavin in a range of food matrices, it can be beneficial if the selected strains survive the gastrointestinal tract, so that the vitamins can be produced in situ at the target site to further enhance delivery and maximize the chance of reaching required daily intake levels ( 16 , 21 ).…”

Section: Introductionmentioning

confidence: 99%

Spontaneous Riboflavin-Overproducing Limosilactobacillus reuteri for Biofortification of Fermented Foods

et al. 2022

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Riboflavin-producing lactic acid bacteria represent a promising and cost-effective strategy for food biofortification, but production levels are typically insufficient to support daily human requirements. In this study, we describe the novel human isolate Limosilactobacillus reuteri AMBV339 as a strong food biofortification candidate. This strain shows a high natural riboflavin (vitamin B2) overproduction of 18.36 μg/ml, biomass production up to 6 × 1010 colony-forming units/ml (in the typical range of model lactobacilli), and pH-lowering capacities to a pH as low as 4.03 in common plant-based (coconut, soy, and oat) and cow milk beverages when cultured up to 72 h at 37°C. These properties were especially pronounced in coconut beverage and butter milk fermentations, and were sustained in co-culture with the model starter Streptococcus thermophilus. Furthermore, L. reuteri AMBV339 grown in laboratory media or in a coconut beverage survived in gastric juice and in a simulated gastrointestinal dialysis model with colon phase (GIDM-colon system) inoculated with fecal material from a healthy volunteer. Passive transport of L. reuteri AMBV339-produced riboflavin occurred in the small intestinal and colon stage of the GIDM system, and active transport via intestinal epithelial Caco-2 monolayers was also demonstrated. L. reuteri AMBV339 did not cause fecal microbiome perturbations in the GIDM-colon system and inhibited enteric bacterial pathogens in vitro. Taken together, our data suggests that L. reuteri AMBV339 represents a promising candidate to provide riboflavin fortification of plant-based and dairy foods, and has a high application potential in the human gastrointestinal tract.

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“…The central carbon metabolism of the model organism used in our experiment, L. cremoris MG1363 (formerly called Lactococcus lactis ssp cremoris ), has been resolved in detail, owing to its importance in milk product fermentation ( Neves et al 2005 ; Teusink and Molenaar 2017 ). Over the course of its domestication to the dairy habitat, L. cremoris has been adapted for fast ‘batch mode’ growth on the glucose moiety of lactose (milk sugar) ( Bachmann et al 2012 ; Kok et al 2017 ; Kleerebezem et al 2020 ). Dairy strains of L. cremoris achieve maximal growth rate on glucose and, when excess glucose is available, catabolite repression downregulates other metabolic pathways in order to maximize growth rate ( Zomer et al 2007 ).…”

Section: Introductionmentioning

confidence: 99%

Trade-Offs Predicted by Metabolic Network Structure Give Rise to Evolutionary Specialization and Phenotypic Diversification

Ekkers

Tusso

Moreno-Gámez

et al. 2022

Molecular Biology and Evolution

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Mitigating trade-offs between different resource-utilization functions is key to an organism’s ecological and evolutionary success. These trade-offs often reflect metabolic constraints with a complex molecular underpinning; therefore, their consequences for evolutionary processes have remained elusive. Here, we investigate how metabolic architecture induces resource utilization constraints and how these constraints, in turn, elicit evolutionary specialization and diversification. Guided by the metabolic network structure of the bacterium Lactococcus cremoris, we selected two carbon sources (fructose and galactose) with predicted co-utilization constraints. By evolving L. cremoris on either fructose, galactose or a mix of both sugars, we imposed selection favoring divergent metabolic specializations or co-utilization of both resources, respectively. Phenotypic characterization revealed the evolution of either fructose or galactose specialists in the single-sugar treatments. In the mixed sugar regime, we observed adaptive diversification: both specialists coexisted, and no generalist evolved. Divergence from the ancestral phenotype occurred at key pathway junctions in the central carbon metabolism. Fructose specialists evolved mutations in the fbp and pfk genes that appear to balance anabolic and catabolic carbon fluxes. Galactose specialists evolved increased expression of pgmA (the primary metabolic bottleneck of galactose metabolism) and silencing of ptnABCD (the main glucose transporter) and ldh (regulator/enzyme of downstream carbon metabolism). Overall, our study shows how metabolic network architecture and historical contingency serve to predict targets of selection and inform the functional interpretation of evolved mutations. The elucidation of the relationship between molecular constraints and phenotypic trade-offs contributes to an integrative understanding of evolutionary specialization and diversification.

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Lifestyle, metabolism and environmental adaptation inLactococcus lactis

Cited by 43 publications

References 168 publications

The growth‐survival trade‐off is hard‐wired in the Lactococcus lactis gene regulation network

The growth‐survival trade‐off is hard‐wired in the Lactococcus lactis gene regulation network

Spontaneous Riboflavin-Overproducing Limosilactobacillus reuteri for Biofortification of Fermented Foods

Trade-Offs Predicted by Metabolic Network Structure Give Rise to Evolutionary Specialization and Phenotypic Diversification

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