Symposium review: Interaction of starter cultures and nonstarter lactic acid bacteria in the cheese environment

Blaya, J.; Barzideh, Zoha; LaPointe, Gisèle

doi:10.3168/jds.2017-13345

Cited by 139 publications

(147 citation statements)

References 98 publications

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“…As Edam cheese is mainly manufactured from pasteurised milk, nonstarter lactic acid bacteria (NSLAB) originating from the raw milk are of little significance. The interaction of starter lactic acid bacteria and NSLAB was reviewed by Blaya et al (), who emphasised that the main source of NSLAB in cheese is the raw milk.…”

Section: Resultsmentioning

confidence: 99%

Salt reduction in film‐ripened, semihard Edam cheese

Hoffmann

Luzzi

Steffens

et al. 2019

Int J of Dairy Tech

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As a potential measure to improve public health, this study aimed to reduce the sodium (Na) content of film-ripened, semihard Edam cheese to ≤0.4 g Na/100 g (≤1 g NaCl/100 g), while retaining typical quality and safety characteristics. For this, mineral salt substitutions containing potassium (K) were compared with simple NaCl reduction in brine, alongside an adjustment of starter cultures in an effort to enhance taste. Desired Na and K values were achieved, and microbial quality was not compromised in Na-reduced Edam after six weeks of ripening. However, all Na-reduced cheeses tasted bitter and were therefore organoleptically unsatisfactory.

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Section: Resultsmentioning

confidence: 99%

Salt reduction in film‐ripened, semihard Edam cheese

Hoffmann

Luzzi

Steffens

et al. 2019

Int J of Dairy Tech

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“…cremoris, but undefined natural starters can also contain strains of Leuconostoc spp. for the ability to ferment citrate [165]. The thermophilic SLAB, including L. helveticus, Streptococcus thermophilus, and L. delbrueckii subsp.…”

Section: Fdf Microbiota Under the Lens Of Metagenomics And Genomicsmentioning

confidence: 99%

Bioprospecting for Bioactive Peptide Production by Lactic Acid Bacteria Isolated from Fermented Dairy Food

2019

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With rapidly ageing populations, the world is experiencing unsustainable healthcare from chronic diseases such as metabolic, cardiovascular, neurodegenerative, and cancer disorders. Healthy diet and lifestyle might contribute to prevent these diseases and potentially enhance health outcomes in patients during and after therapy. Fermented dairy foods (FDFs) found their origin concurrently with human civilization for increasing milk shelf-life and enhancing sensorial attributes. Although the probiotic concept has been developed more recently, FDFs, such as milks and yoghurt, have been unconsciously associated with health-promoting effects since ancient times. These health benefits rely not only on the occurrence of fermentation-associated live microbes (mainly lactic acid bacteria; LAB), but also on the pro-health molecules (PHMs) mostly derived from microbial conversion of food compounds. Therefore, there is a renaissance of interest toward traditional fermented food as a reservoir of novel microbes producing PHMs, and “hyperfoods” can be tailored to deliver these healthy molecules to humans. In FDFs, the main PHMs are bioactive peptides (BPs) released from milk proteins by microbial proteolysis. BPs display a pattern of biofunctions such as anti-hypertensive, antioxidant, immuno-modulatory, and anti-microbial activities. Here, we summarized the BPs most frequently encountered in dairy food and their biological activities; we reviewed the main studies exploring the potential of dairy microbiota to release BPs; and delineated the main effectors of the proteolytic LAB systems responsible for BPs release.

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“…the biochemical reactions occurring in cheese during ripening (1,2). Primary and secondary starters, nonstarter lactic acid bacteria (NSLAB) (3), adjunct/attenuated cultures (4)(5)(6)(7), and microbial populations coming from the milk and cheese manufacturing environment shape the cheese microbiota (8)(9)(10)(11). Biotic and abiotic drivers affect the establishment, assembly, and metabolism of the cheese microbiota, which is involved in the development of cheese sensory and nutritional features.…”

mentioning

confidence: 99%

“…Biotic and abiotic drivers affect the establishment, assembly, and metabolism of the cheese microbiota, which is involved in the development of cheese sensory and nutritional features. Indeed, unbalanced microbiota and related metabolic activities may increase the risk of cheese off flavors and odors (9,(12)(13)(14). Deep investigation of the microbial interactions during cheese ripening allows the manufacture of cheeses with improved and consistent quality, reducing costs and improving appreciation by consumers (13,15).…”

mentioning

confidence: 99%

Attenuated Lactococcus lactis and Surface Bacteria as Tools for Conditioning the Microbiota and Driving the Ripening of Semisoft Caciotta Cheese

Calasso

Minervini

Filippis

et al. 2020

Appl Environ Microbiol

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This study aimed at establishing the effects of attenuated starters and surface bacteria on various features of caciotta cheese. The cheese undergoes a ripening period during which the house microbiota contaminates the surface. Conventional cheese (the control cheese [CC]) is made using only primary starters. Primary starters and attenuated (i.e., unable to grow and synthesize lactic acid) Lactococcus lactis (Lc. lactis) subsp. lactis were used to produce caciotta cheese without (ATT cheese) or with an inoculum of surface bacteria: (i) Leuconostoc lactis (Le. lactis) (LL cheese), (ii) Vibrio casei (VC cheese), (iii) Staphylococcus equorum (SE cheese), (iv) Brochothrix thermosphacta (BX cheese), and (v) a mixture of all four (MIX cheese). Attenuated Lc. lactis increased microbial diversity during cheese ripening. At the core, attenuated starter mainly increased indigenous lactococci and Lactobacillus delbrueckii group bacteria. At the surface, the main effect was on Macrococcus caseolyticus. Autochthonous Le. lactis strains took advantage of the attenuated starter, becoming dominant. Adjunct Le. lactis positively affected Lactobacillus sakei group bacteria on the LL cheese surface. Adjunct V. casei, S. equorum, and B. thermosphacta did not become dominant. Surfaces of VC, SE, and BX cheeses mainly harbored Staphylococcus succinus. Peptidase activities were higher in cheeses made with attenuated starter than in CC, which had the lowest concentration of free amino acids. Based on the enzymatic activities of adjunct Le. lactis, LL and MIX cheeses exhibited the highest glutamate dehydrogenase, cystathionine-␥-lyase, and esterase activities. As shown by multivariate statistical analyses, LL and MIX cheeses showed the highest similarity for microbiological and biochemical features. LL and MIX cheeses received the highest scores for overall sensory acceptability. IMPORTANCE This study provides in-depth knowledge of the effects of attenuated starters and surface bacterial strains on the microbiota and related metabolic activities during cheese ripening. The use of attenuated Lc. lactis strongly impacted the microbiota assembly of caciotta cheese. This led to improved biochemical and sensory features compared to conventional cheese. Among surface bacterial strains, Le. lactis played a key role in the metabolic activities involved in cheese ripening. This resulted in an improvement of the sensory quality of caciotta cheese. The use of attenuated lactic acid bacteria and the surface adjunct Le. lactis could be a useful biotechnology to improve the flavor formation of caciotta cheese.

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Symposium review: Interaction of starter cultures and nonstarter lactic acid bacteria in the cheese environment

Cited by 139 publications

References 98 publications

Salt reduction in film‐ripened, semihard Edam cheese

Salt reduction in film‐ripened, semihard Edam cheese

Bioprospecting for Bioactive Peptide Production by Lactic Acid Bacteria Isolated from Fermented Dairy Food

Attenuated Lactococcus lactis and Surface Bacteria as Tools for Conditioning the Microbiota and Driving the Ripening of Semisoft Caciotta Cheese

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