Lactic acid bacteria involved in food fermentations and their present and future uses in food industry

The antimicrobial activity of polyphenol-enriched extracts from industrial plant by-products (strawberry and bilberry press residues and distilled rose petals) against probiotic lactic acid bacteria (Lactobacillus delbrueckii subsp. bulgaricus – S10 and S19; Lactobacillus rhamnosus – YW and S25; Lactobacillus gasseri – S20; Streptococcus thermophilus – S13 and S32) was investigated. The minimum inhibitory concentration (MIC) in most strains tested was found to be relatively high (from 6.25 mg.mL-1 to 12.50 mg.mL-1). The maximum concentration of polyphenols without inhibitory effect (MCWI) ranges from 0.390mg.mL-1 to 0.781mg.mL-1. The results obtained in the present study showed that among the tested lactic acid bacteria Lactobacillus delbrueckii subsp. bulgaricus – S19, Lactobacillus rhamnosus – YW and Streptococcus thermophilus – S13 had the best growth characteristics in polyphenol-enriched culture medium. These strains had the highest MIC and MCWI values and could be used as starter cultures for polyphenol-fortified fermented milks. Practical applications: The use of polyphenol-enriched extracts from industrial plant by-products (waste) – distilled rose petals (by-products of rose oil production) and strawberry and bilberry press residues (by-products of fruit juice production) contribute for improving the economic effect and for solving environmental problems in food industry. Development of functional fermented milks with combination of probiotic starter cultures and polyphenol extracts is current and perspective direction of food industry.

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Editorial: Lactic Acid Bacteria Within the Food Industry: What Is New on Their Technological and Functional Role

Frontiers in Microbiology ◽

10.3389/fmicb.2021.711013 ◽

2021 ◽

Vol 12 ◽

Author(s):

Paola Lavermicocca ◽

Cristina Reguant ◽

Joaquin Bautista-Gallego

Keyword(s):

Lactic Acid ◽

Lactic Acid Bacteria ◽

Functional Role ◽

Food Industry

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Metabolism Characteristics of Lactic Acid Bacteria and the Expanding Applications in Food Industry

Frontiers in Bioengineering and Biotechnology ◽

10.3389/fbioe.2021.612285 ◽

2021 ◽

Vol 9 ◽

Author(s):

Yaqi Wang ◽

Jiangtao Wu ◽

Mengxin Lv ◽

Zhen Shao ◽

Meluleki Hungwe ◽

...

Keyword(s):

Lactic Acid ◽

Lactic Acid Bacteria ◽

Food Industry ◽

Short Chain Fatty Acids ◽

Fermented Food ◽

The Body ◽

Fermented Foods ◽

Metabolic Characteristics ◽

The One

Lactic acid bacteria are a kind of microorganisms that can ferment carbohydrates to produce lactic acid, and are currently widely used in the fermented food industry. In recent years, with the excellent role of lactic acid bacteria in the food industry and probiotic functions, their microbial metabolic characteristics have also attracted more attention. Lactic acid bacteria can decompose macromolecular substances in food, including degradation of indigestible polysaccharides and transformation of undesirable flavor substances. Meanwhile, they can also produce a variety of products including short-chain fatty acids, amines, bacteriocins, vitamins and exopolysaccharides during metabolism. Based on the above-mentioned metabolic characteristics, lactic acid bacteria have shown a variety of expanded applications in the food industry. On the one hand, they are used to improve the flavor of fermented foods, increase the nutrition of foods, reduce harmful substances, increase shelf life, and so on. On the other hand, they can be used as probiotics to promote health in the body. This article reviews and prospects the important metabolites in the expanded application of lactic acid bacteria from the perspective of bioengineering and biotechnology.

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Lactic Acid Bacterial Production of Exopolysaccharides from Fruit and Vegetables and Associated Benefits

Fermentation ◽

10.3390/fermentation6040115 ◽

2020 ◽

Vol 6 (4) ◽

pp. 115

Author(s):

Marie Guérin ◽

Christine Robert-Da Silva ◽

Cyrielle Garcia ◽

Fabienne Remize

Keyword(s):

Lactic Acid ◽

Chemical Composition ◽

Lactic Acid Bacteria ◽

Food Industry ◽

Functional Foods ◽

Fruits And Vegetables ◽

Fruit And Vegetables ◽

Scientific Investigations ◽

Composition And Structure ◽

Regulation Mode

Microbial polysaccharides have interesting and attractive characteristics for the food industry, especially when produced by food grade bacteria. Polysaccharides produced by lactic acid bacteria (LAB) during fermentation are extracellular macromolecules of either homo or hetero polysaccharidic nature, and can be classified according to their chemical composition and structure. The most prominent exopolysaccharide (EPS) producing lactic acid bacteria are Lactobacillus, Leuconostoc, Weissella, Lactococcus, Streptococcus, Pediococcus and Bifidobacterium sp. The EPS biosynthesis and regulation pathways are under the dependence of numerous factors as producing-species or strain, nutrient availability, and environmental conditions, resulting in varied carbohydrate compositions and beneficial properties. The interest is growing for fruits and vegetables fermented products, as new functional foods, and the present review is focused on exploring the EPS that could derive from lactic fermented fruit and vegetables. The chemical composition, biosynthetic pathways of EPS and their regulation mode is reported. The consequences of EPS on food quality, especially texture, are explored in relation to producing species. Attention is given to the scientific investigations on health benefits attributed to EPS such as prebiotic, antioxidant, anti-inflammatory and cholesterol lowering activities.

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Effect of Lactobacillus rhamnosus on Physicochemical Properties of Fermented Plant-Based Raw Materials

Foods ◽

10.3390/foods9091182 ◽

2020 ◽

Vol 9 (9) ◽

pp. 1182 ◽

Cited By ~ 2

Author(s):

Carmen Masiá ◽

Poul Erik Jensen ◽

Patrizia Buldo

Keyword(s):

Lactic Acid ◽

Lactic Acid Bacteria ◽

Physicochemical Properties ◽

Food Industry ◽

Raw Materials ◽

Lactobacillus Rhamnosus ◽

Titratable Acidity ◽

Fermentation Time ◽

Trained Panel ◽

Volatile Organic

Texture and flavor are currently the main challenges in the development of plant-based dairy alternatives. To overcome them, the potential of microorganisms for fermentation of plant-based raw materials is generating great interest in the food industry. This study examines the effect of Lactobacillus rhamnosus, LGG® (LGG® is a trademark of Chr. Hansen A/S) on the physicochemical properties of fermented soy, oat, and coconut. LGG® was combined with different lactic acid bacteria (LAB) strains and Bifidobacterium, BB-12® (BB-12® is a trademark of Chr. Hansen A/S). Acidification, titratable acidity, and growth of LGG® and BB-12® were evaluated. Oscillation and flow tests were performed to analyze the rheological properties of fermented samples. Acids, carbohydrates, and volatile organic compounds in fermented samples were identified, and a sensory evaluation with a trained panel was conducted. LGG® reduced fermentation time in all three bases. LGG® and BB-12® grew in all fermented raw materials above 107 CFU/g. LGG® had no significant effect on rheological behavior of the samples. Acetoin levels increased and acetaldehyde content decreased in the presence of LGG® in all three bases. Diacetyl levels increased in fermented oat and coconut samples when LGG® was combined with YOFLEX® YF-L01 and NU-TRISH® BY-01 (YOFLEX® and NU-TRISH® are trademarks of Chr. Hansen A/S). In all fermented oat samples, LGG® significantly enhanced fermented flavor notes, such as sourness, lemon, and fruity taste, which in turn led to reduced perception of the attributes related to the base. In fermented coconut samples, gel firmness perception was significantly improved in the presence of LGG®. These findings suggest supplementation of LAB cultures with LGG® to improve fermentation time and sensory perception of fermented plant-based products.

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Role of Lactic Acid Bacteria as a Biosanitizer To Prevent Attachment of Listeria monocytogenes F6900 on Deli Slicer Contact Surfaces

Journal of Food Protection ◽

10.4315/0362-028x.jfp-12-072 ◽

2012 ◽

Vol 75 (8) ◽

pp. 1429-1436 ◽

Cited By ~ 14

Author(s):

JEAN BAPTISTE NDAHETUYE ◽

OK KYUNG KOO ◽

CORLISS A. O'BRYAN ◽

STEVEN C. RICKE ◽

PHILIP G. CRANDALL

Keyword(s):

Stainless Steel ◽

Lactic Acid ◽

Listeria Monocytogenes ◽

Lactic Acid Bacteria ◽

Food Industry ◽

Colorimetric Method ◽

Lactobacillus Amylovorus ◽

Total Carbohydrates ◽

Lactobacillus Animalis

The study was conducted to evaluate the attachment of three lactic acid bacteria (LAB) strains and their combination in a cocktail, to stainless steel coupons from a deli slicer, and their ability to inhibit the attachment of Listeria monocytogenes. In a previous study, three LAB strains, Pediococcus acidilactici, Lactobacillus amylovorus, and Lactobacillus animalis, were isolated from ready-to-eat meat and exhibited antilisterial effect. In the study reported here, hydrophobicity tests were determined according to the method of microbial adhesion to solvent. The attachment of the cells was evaluated on stainless steel coupons from deli slicers. Extracellular carbohydrates were determined with a colorimetric method. Based on these tests, L. animalis exhibited the greatest hydrophobicity (26.3%), and its adherence increased sharply from 24 to 72 h, whereas L. amylovorus yielded the lowest hydrophobicity (3.86%) and was weakly adherent. Although P. acidilactici had moderate hydrophobicity (10.1%), it adhered strongly. The attached LAB strains produced significantly (P < 0.05) higher total carbohydrates than their planktonic counterparts did, which is an important characteristic for attachment. Three conditions were simulated to evaluate the ability of the LAB cocktail (108 CFU/ml) to competitively exclude L. monocytogenes (103 CFU/ml) on the surface of the coupons. The coupons were pretreated with the LAB cocktail for 24 h prior to the addition of L. monocytogenes, simultaneously treated with the LAB cocktail and L. monocytogenes, or pretreated with L. monocytogenes 24 h prior to the addition of the LAB cocktail. The LAB cocktail was able to reduce the attachment L. monocytogenes significantly (P < 0.05). The LAB cocktail indicated potential attachment on stainless steel and bacteriostatic activity toward L. monocytogenes attached on stainless steel, which indicates a possible role for LAB as a biosanitizer in the food industry.

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Stress Physiology of Lactic Acid Bacteria

Microbiology and Molecular Biology Reviews ◽

10.1128/mmbr.00076-15 ◽

2016 ◽

Vol 80 (3) ◽

pp. 837-890 ◽

Cited By ~ 185

Author(s):

Konstantinos Papadimitriou ◽

Ángel Alegría ◽

Peter A. Bron ◽

Maria de Angelis ◽

Marco Gobbetti ◽

...

Keyword(s):

Lactic Acid ◽

Lactic Acid Bacteria ◽

Stress Responses ◽

Defense Mechanisms ◽

Food Industry ◽

Cell Envelope ◽

Stress Physiology ◽

Content Type ◽

Envelope Stress ◽

Cell Energy

SUMMARYLactic acid bacteria (LAB) are important starter, commensal, or pathogenic microorganisms. The stress physiology of LAB has been studied in depth for over 2 decades, fueled mostly by the technological implications of LAB robustness in the food industry. Survival of probiotic LAB in the host and the potential relatedness of LAB virulence to their stress resilience have intensified interest in the field. Thus, a wealth of information concerning stress responses exists today for strains as diverse as starter (e.g.,Lactococcus lactis), probiotic (e.g., severalLactobacillusspp.), and pathogenic (e.g.,EnterococcusandStreptococcusspp.) LAB. Here we present the state of the art for LAB stress behavior. We describe the multitude of stresses that LAB are confronted with, and we present the experimental context used to study the stress responses of LAB, focusing on adaptation, habituation, and cross-protection as well as on self-induced multistress resistance in stationary phase, biofilms, and dormancy. We also consider stress responses at the population and single-cell levels. Subsequently, we concentrate on the stress defense mechanisms that have been reported to date, grouping them according to their direct participation in preserving cell energy, defending macromolecules, and protecting the cell envelope. Stress-induced responses of probiotic LAB and commensal/pathogenic LAB are highlighted separately due to the complexity of the peculiar multistress conditions to which these bacteria are subjected in their hosts. Induction of prophages under environmental stresses is then discussed. Finally, we present systems-based strategies to characterize the “stressome” of LAB and to engineer new food-related and probiotic LAB with improved stress tolerance.

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