Lactic Acid Bacteria: Food Safety and Human Health Applications
Abstract
:1. Introduction
2. Lactic Acid Bacteria
2.1. Taxonomic Classification of Lactic Acid Bacteria
2.2. Niche or Habitat of Lactic Acid Bacteria
2.3. Lactic Acid Bacteria in Bio-Preservation
2.4. Lactic Acid Bacteria in Fermented Foods
2.5. Milk Fermentation with Lactic Acid Bacteria
2.6. Lactic Acid Bacteria as an Essential Strain in Dairy Starter Cultures
2.7. Lactobacillus delbrueckii subsp. bulgaricus
3. History of Probiotics
3.1. Origin of Probiotics
3.2. Mechanism of Probiotics
- (i)
- Probiotics can modulate the host’s defenses which include the innate as well as the acquired immune system. This mode of action is most critical for prevention and therapy for infectious diseases but also for the treatment of chronic inflammation of the gastrointestinal tract.
- (ii)
- Probiotics could also directly impact other microorganisms, commensal, and/or pathogenic ones in general. This property could be of immense benefit and vital in prevention and therapy for infections and the overall restoration of the microbial equilibrium in the gut.
- (iii)
- Additionally, probiotic effects may be linked to actions affecting microbial products such as toxins and host products, e.g., bile salts and food ingredients. This property may result in the inactivation of toxins and aids in detoxification in the gastrointestinal gut. It is also worth noting that the kind of effects depicted by certain strains of probiotics largely depends on the strain’s metabolic properties, the molecules presented on their surfaces or on their secreted components.
- Probiotics compete against pathogenic bacteria to bind to intestinal epithelial cells [86].
- Probiotics enhance the intestinal epithelial barrier function by increasing mucin production, preventing pathogens from causing injury to the epithelium and reducing cell permeability. In addition, probiotics also enhance the mucosal barrier function by inducing the expression of antimicrobial peptides such as defensins [86].
- They inhibit pathogenic growth through the secretion of antimicrobial peptides such as bacteriocins and reuterin. For example, lactic acid bacteria inhibit pathogen growth by creating an acidic environment through the production of organic acids [86].
- Probiotics also stimulate the production of serum Immunoglobin A (IgA) and secrete IgA which plays a vital role in intestinal humoral immunity [86].
- They enhance phagocytosis, increase the activity of natural killer cells, promote cell-mediated immunity, and stimulate various other non-specific immune responses against pathogens [86].
- Probiotics down-regulate pro-inflammatory cytokine production, prevent apoptosis, and suppress the proliferation of T cells thus preventing various inflammatory conditions [86].
- They produce hydrogen peroxide which suppresses pathogens associated with bacterial vaginosis [88].
3.3. Probiotics and Human Health
3.4. Health Benefits of Probiotics in Some Disease Conditions
3.4.1. Lactose Intolerance
3.4.2. Diabetes and Obesity
3.4.3. Acute Diarrheal Disease
3.4.4. Inflammatory Bowel Diseases and Irritable Bowel Syndrome
3.4.5. Cancer
3.4.6. Cardiovascular Diseases
3.4.7. Urogenital Infections
3.4.8. Allergy
3.4.9. Gut–Brain Axis
3.5. Antiviral Activity of Lactic Acid Bacteria
3.5.1. Mechanisms of Probiotic Action on Viruses
- Probiotic bacteria is irreversibly attached to the virus, therefore limiting the virus’ binding effect to the host cell receptor.
- Probiotic adhesive property is capable of obstructing viral attachment on the epithelial surface through steric hindrance.
- Virus replication is inhibited by mucin attachments produced by probiotics through the process of mucosal regeneration.
- Antimicrobial metabolites produced by probiotics act against pathogens.
- Synthesis of dehydrogenase by probiotics may possess and contribute to antiviral processes.
- Epithelial cells generally promote the modulation of immune responses.
- Macrophages and dendritic cells are induced, thus stimulating the immune response.
- Viral cells are destroyed by the joint action of cluster of differentiation 8 (CD8) T cells and T lymphocytes that differentiate into cytotoxic T lymphocytes (CTLs).
- Further differentiation of CD4 and T lymphocytes into helper T cells (Th1 and Th2) occurs.
- Activated phagocytes eliminate viruses through induction of the Th1 cells.
- B-cells are proliferated by stimulation of Th2, which migrates to secondary lymphatic organs resident in mucosa-associated lymphoid tissue (MALT). Differentiation of B cells into Ig producing plasma cells occurs afterward.
- Antibodies activated during this immune response completely eliminate the virus.
3.5.2. Strain-Specific Antiviral Properties of Lactic Acid Bacteria
3.5.3. Antiviral Properties of Bacteriocins
4. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Antimicrobial Compounds/Metabolites | Characteristic Property | Species | References |
---|---|---|---|
Organic acids, hydrogen peroxide | Promotes significant inhibitory, antagonistic effect and an important target for pathogens (Gram-positives and Gram-negatives) and food spoilage microorganisms | Lactobacillus species | Nagpal et al., 2012 [28]; Papadimitriou et al., 2015 [29]; Ponce et al., 2008 [30] |
Lactoperoxidase system | Thiocyanate and hydrogen peroxide have a broad-spectrum antibacterial action on pathogens | Lactobacillus species | Seifu et al., 2005 [31] |
Bacteriocins | Characteristic Property | Species/Compound | References |
Class I Bacteriocins (Lantibiotics) | Antimicrobial peptides synthesized ribosomally and have an inhibitory effect on pathogens. Widely used in food preservation operations. Lantibiotics are post-translationally modified and are low molecular weight peptides (<5 kDa). Consists of superior amino acids i.e., lanthionine and β-methyllanthionine |
| Yang et al., 2014 [24]; Mokoena 2017 [10], Perez et al., 2014 [3] |
Class II Bacteriocins (Non Lantibiotics) | Heat stable and small peptides with a high molecular weight (5–10 kDa). They are non-lanthionine molecules with or without post-translational modifications | Yang et al., 2014 [24]; Mokoena 2017 [10], Perez et al., 2014 [3] | |
Class IIa Bacteriocins (Non Lantibiotics) | Functional peptides are synthesized from several genes as a requirement | Yang et al., 2014 [24]; Mokoena 2017 [10], Perez et al., 2014 [3] | |
Bacteriocins | Characteristic Property | Species/Compound | References |
Class IIb Bacteriocins (Non Lantibiotics) | Two different peptides, mostly linear coupled with or without post translational modifications at the C-terminal are required |
| Yang et al., 2014 [24]; Mokoena 2017 [10], Perez et al., 2014 [3] |
Class IIc Bacteriocins (Non Lantibiotics) | Bacteriocins have a circular structure with both the N- and C-terminals linked by covalent bonds | Yang et al., 2014 [24]; Mokoena 2017 [10], Perez et al., 2014 [3] | |
Class III Bacteriocins (Non-lantibiotics) Class IIIa Bacteriocins (Bacteriolytic) Class IIIb Bacteriocins (Non-lytic) | Large heat-labile peptides with molecular weight > 30 kDa. They are sub-classified under Class IIIa and Class IIIb. Class IIIa they are mainly bacteriolysins. Lysostaphin, is an antimicrobial peptide produced by staphylococci that targets Gram-positives and destroys them. Class IIIb (Helveticin) is a non-lytic protein produced from Gram-positive bacteria Lactobacillus helveticus | Ibrahim, 2019 [32]; Ramu et al., (2015) [33]. | |
Class IV Bacteriocins | Bacteriocins classified as complex with compositions of lipids and carbohydrates moieties | Ibrahim, 2019 [32]; Ramu et al., (2015) [33]. |
Traditional Fermented Foods | Microbiota | Associated Action | References |
---|---|---|---|
Dahi | Lactobacillus acidophilus | Production of antibacterial substances | Balamurugan et al., 2014 [37] |
Kefir | Lactobacillus kefir, Lactobacillus kefiranofaciens, and Lactobacillus kefirgranum | Production of bacteriocin enhances antibacterial activity Epithelial cells of the intestine have reduced inflammation Serum cholesterol level is reduced Produce an EPS known as kefiran. | Luo et al., 2011 [38]; Seo et al., 2018 [39]; Wang et al., 2008 [40]; Bonczar et al., 2016 [41] |
Tofu | Lactobacillus plantarum | Antioxidant activity | Li et al., 2012 [42] |
Koumiss | Lactobacillus sp. | Excellent antimicrobial properties against pathogens | Guo et al., 2015 [43] |
Swiss Cheese | Lactobacillus helveticus R389 | Enhancement of the immune system by increasing IgA and CD4 positive cells. | Ghosh et al., 2019 [36] |
Nunu | Lactobacillus plantarum, Lactobacillus fermentum, and Saccharomyces cerevisiae | Produces EPS, and β-galactosidase Produces bacteriocins known as plantaricins promoting antibacterial activity against pathogens | Akabanda et al., 2013 [44]; Behera et al., 2018 [45] |
Korean kimchi | Lactobacillus plantarum | Antimicrobial activity against pathogens | Kwak et al., 2017 [46] |
Fermented Dairy Foods | Starter Cultures | References |
---|---|---|
Hard cheese without eyes | Lactococcus lactis lactis, Lactococcus lactis ssp. cremoris | Settani et al., 2013 [48] |
Kefir | Lactobacillus kefir, Lactobacillus kefiranofaciens, | Luo et al., 2011 [38] |
Yogurt | Lb. acidophilus, S. thermophilus, Lb. delbrueckii ssp. bulgaricus | Panesar, 2011 [49], Hati et al., 2013 [2] |
Swiss cheese | Lactobacillus delbrueckii ssp. lactis, Lb. helveticus, Lb. casei | Daly et al., 2010 [50] |
Zabady | Lb. delbrueckii ssp. bulgaricus, S. thermophilus | Abou-Donia, 2004 [51] |
Bulgarian butter milk | L. delbrueckii subsp. bulgaricus | Panesar, 2011 [49] |
Nyarmie | Lactobacillus sp., Lactococcus lactis | Obodai & Dodd, 2006 [52] |
Starter bacteria | Functionality | Benefits | References |
---|---|---|---|
Lactobacillus plantarum, Lactococcus lactis | Production of Bacteriocins | Bio-preservation | Todorov et al., 2010 [55]; Biscola et al., 2013 [56] |
Lactobacillus sp. (EPS efficient) | Formation of stabilizers and production of exopolysaccharides | Enhanced viscosity and body development (polysaccharide materials) | Cerning, 1995 [57] |
Vitamins producing lactic acid (Strepotococci and propionibacteria) | Vitamin content in fermented dairy products are improved | Enhances the overall health of the bacteria, Promotes vitamin malnutrition | Hati et al., 2013 [2] |
Leuconostoc spp. | Acid production | Promotes flavor development, Formation of gels | Bintsis, 2018 [1] |
Lactococcus lactis ssp. cremoris | Proteolyis and lipolysis | Ensures accelerated ripening and maturation of cheese | Hati et al., 2013 [2] |
Probiotic Strain | Health Benefits | Mechanism of Action | References |
---|---|---|---|
Lactic acid bacteria | Prevention and treatment of colon cancer | Ensures biodegradation of susceptible and potential carcinogens Boost the immune response system of the host and inhibits pro-cancerous enzymatic activity of colonic microorganisms | Kahouli et al., 2013 [103] |
Bifidobacterium bifidum | Inhibition of enteric pathogens | Prevents and reduces diarrhea Inhibits invasive pathogens by secretion of acids and increases antibacterial action of the intestinal microflora | Gill & Prasad, 2008 [104]; Russell et al., 2011 [105] |
Bifidobacterium lactis, L. bulgaricus, L. plantarum, L. acidophilus | Irritable bowel syndrome and constipation prevention and treatment | Alleviates symptoms of irritable bowel syndrome. Modulates and alters gastrointestinal microflora to offset abnormal conditions. | Guerra et al., 2011 [106]; Mena et al., 2013 [107] |
Lactobacillus, Bifidobacterium | Treatment of Helicobacter pylori infection | Epithelial and mucosal cells are competitively colonized. Production of bacteriocins and organic acids to impede action of the bacteria. | Hsieh et al., 2012 [108] |
Bifidobacterium breve | Rotaviral gastroenteritis treatment | Promotes and boosts the production of anti-rotavirus IgA or anti-influenza virus | Gonzalez-Ochoa et al., (2017) [109] |
Oxalobacter formigenes Lactobacillus and Bifidobacterium species | Treatment of kidney or Urogenital infections | Metabolic and mopping up action on toxic compounds. | Roswitha et al., 2013 [110] |
Lactobacillus acidophilus NCFM | Diabetes and obesity | Minimizes risks associated with type 2 diabetes mellitus and enhances host metabolic system ensuring weight management | Andreasen et al., 2010 [111] Sanchez et al., 2013 [112] |
Lactic Acid Bacteria Strain | Origin of Strain | Virus Evaluated | Mode of Action | References |
---|---|---|---|---|
L. fermentum CECT5716 | Human breast milk | Influenza virus | Enhances the response of antibodies | Boge et al., 2009 [163] |
Lactobacillus delbrueckii ssp. Bulgaricus OLL1073R-1 (1073R-1) | Fermented food (Yogurt) | Influenza virus | Promotes antagonistic antibodies | Nagai et al., 2011 [154] |
L. plantarum YML009 | Fermented food (Kimchi) | H1N1 Influenza virus | Activation of Th1 immune response | Rather et al., 2014 [164] |
L. rhamnosus CRL1505 | Commercial probiotic strains | Respiratory syncytial virus (RSV) | Production of IFN-γ and Ils | Villena et al., 2011 [165] |
Lactobacillus gasseri SBT2055 (LG2055) | Human feces | RSV | Proinflammatory activity | Eguchi et al., 2019 [166] |
Enterococcus durans | Goat milk | Herpes Simplex Virus (HSV-1) and Human papillomavirus (PV-1) | Decreases viral cell replication | Cavicchioli et al., 2018 [167] |
L. acidophilus strain NCFM | Newborn feces | Reduce influenza like symptoms | Immunomodulation | Leyer et al., 2009 [168] |
Lactobacillus ruminis SPM0211 | Isolated from a young Korean girl | Rotavirus (ROV) | Immunomodulation and promotion of interferons (IFNs) | Kang et al., 2015 [169] |
L. rhamnosus | Gut flora | HSV-1 | Stimulation of macrophages and elimination of HSV-1 | Khani et al., 2012 [170] |
L. plantarum CNRZ 1997 | - | H1N1 strain A | Proinflammatory response | Kechaou et al., 2013 [171] |
E. faecium NCIMB 10415 | - | Transmissible gastroenteritis virus) TGEV | Promotion of nitric oxide (NO) production and secretion of Interleukins (IL-6 and IL-8) | Chai et al., 2013 [172] |
L. acidophilus | - | ROVs | Reduction in duration of diarrhea | Grandy et al., 2010 [173] |
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Ayivi, R.D.; Gyawali, R.; Krastanov, A.; Aljaloud, S.O.; Worku, M.; Tahergorabi, R.; Silva, R.C.d.; Ibrahim, S.A. Lactic Acid Bacteria: Food Safety and Human Health Applications. Dairy 2020, 1, 202-232. https://doi.org/10.3390/dairy1030015
Ayivi RD, Gyawali R, Krastanov A, Aljaloud SO, Worku M, Tahergorabi R, Silva RCd, Ibrahim SA. Lactic Acid Bacteria: Food Safety and Human Health Applications. Dairy. 2020; 1(3):202-232. https://doi.org/10.3390/dairy1030015
Chicago/Turabian StyleAyivi, Raphael D., Rabin Gyawali, Albert Krastanov, Sulaiman O. Aljaloud, Mulumebet Worku, Reza Tahergorabi, Roberta Claro da Silva, and Salam A. Ibrahim. 2020. "Lactic Acid Bacteria: Food Safety and Human Health Applications" Dairy 1, no. 3: 202-232. https://doi.org/10.3390/dairy1030015
APA StyleAyivi, R. D., Gyawali, R., Krastanov, A., Aljaloud, S. O., Worku, M., Tahergorabi, R., Silva, R. C. d., & Ibrahim, S. A. (2020). Lactic Acid Bacteria: Food Safety and Human Health Applications. Dairy, 1(3), 202-232. https://doi.org/10.3390/dairy1030015