Bacterial-Based Strategies to Hydrolyze Gluten Peptides and Protect Intestinal Mucosa

Cristofori, F.; Francavilla, Ruggiero; Capobianco, Daniela; Dargenio, Vanessa Nadia; Filardo, Simone; Mastromarino, Paola

doi:10.3389/fimmu.2020.567801

Cited by 15 publications

(13 citation statements)

References 38 publications

(45 reference statements)

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“…The increase in ELISA response after fermentation is possibly due to an increase in the number of polypeptide units with single epitopes due to gluten proteolysis/degradation. Degradation of gluten proteins by the cell envelope-associated proteinases of lactic acid bacteria present in the yogurt starter culture has been reported previously. , The increased ELISA response also suggests that the proteolytic activity accompanying 24 h of fermentation did not completely degrade all gluten proteins.…”

Section: Resultssupporting

confidence: 63%

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Multiplex-Competitive ELISA for Detection and Characterization of Gluten during Yogurt Fermentation: Effects of Changes in Certain Fermentation Conditions on Gluten Protein Profiles and Method Reproducibility Assessment

Panda

Cho

Ivens

et al. 2021

J. Agric. Food Chem.

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The protein/peptide profiles of gluten during yogurt fermentation were evaluated using an optimized multiplexcompetitive ELISA by preparing yogurts incurred with gluten at different concentrations and by varying certain fermentation conditions. Analysis indicated that epitope-specific responses with antibody binding to glutenin epitopes decreased less during longer fermentation times or at higher starter culture concentrations relative to gliadins. Incomplete proteolysis was observed after 24 h of fermentation, which became more efficient as fermentation time was increased. Western blot confirmed the results of ELISA. Cluster analysis indicated that out of the investigated parameters, fermentation time is the only parameter that could affect the overall gluten protein/peptide profiles during yogurt fermentation. This parameter needs consideration in evaluating the suitability of calibrant(s) to be used with the multiplex-competitive ELISA or any other methods to ensure accurate quantitation of gluten in yogurts and potentially in other foods with similar fermentation chemistry. A small-scale multilaboratory evaluation indicated that the multiplexcompetitive ELISA has good analytical reproducibility (average interlaboratory % CV of 28−41%).

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Section: Resultssupporting

confidence: 63%

“…Degradation of gluten proteins by the cell envelope-associated proteinases of lactic acid bacteria present in the yogurt starter culture has been reported previously. 38,39 The increased ELISA response also suggests that the proteolytic activity accompanying 24 h of fermentation did not completely degrade all gluten proteins.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Multiplex-Competitive ELISA for Detection and Characterization of Gluten during Yogurt Fermentation: Effects of Changes in Certain Fermentation Conditions on Gluten Protein Profiles and Method Reproducibility Assessment

Panda

Cho

Ivens

et al. 2021

J. Agric. Food Chem.

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“…Lactobacilli and Bifidobacterium are considered essential intestinal microbiota having beneficial effects on human health and are widely used in the formulation of probiotic products. Therapy with probiotics containing bacteria that can degrade gluten could be a possible new strategy for the complementary treatment of CeD patients [ 126 ]. Bifidobacterium species showed significant digestion of gluten protein and reduced cytotoxicity and pro-inflammatory responses [ 127 ].…”

Section: Dietary Interventions For Complementing the Gfd And Beyondmentioning

confidence: 99%

Celiac Disease and Possible Dietary Interventions: From Enzymes and Probiotics to Postbiotics and Viruses

Wagh

Lammers²,

Padul

et al. 2022

IJMS

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Celiac Disease (CeD) is a chronic small intestinal immune-mediated enteropathy caused by the ingestion of dietary gluten proteins in genetically susceptible individuals. CeD is one of the most common autoimmune diseases, affecting around 1.4% of the population globally. To date, the only acceptable treatment for CeD is strict, lifelong adherence to a gluten-free diet (GFD). However, in some cases, GFD does not alter gluten-induced symptoms. In addition, strict adherence to a GFD reduces patients’ quality of life and is often a socio-economic burden. This narrative review offers an interdisciplinary overview of CeD pathomechanism and the limitations of GFD, focusing on current research on possible dietary interventions. It concentrates on the recent research on the degradation of gluten through enzymes, the modulation of the microbiome, and the different types of “biotics” strategies, from probiotics to the less explored “viromebiotics” as possible beneficial complementary interventions for CeD management. The final aim is to set the context for future research that may consider the role of gluten proteins and the microbiome in nutritional and non-pharmacological interventions for CeD beyond the sole use of the GFD.

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“…GM is involved in several metabolic processes and its susceptibility to the general food quality and the specific quality of wheat is well established ( 11 ). In particular, considering that GM plays a pivotal role in gut-associated immune system homeostasis, it has been demonstrated that wheat peptides, only partially digested by intestinal proteases, can have an increased or reduced immunogenicity depending on their degrading bacteria, influencing the possibility of developing wheat-related disorders ( 12 ). Another core GM activity is carbohydrate fermentation with the consequent production of short- (SCFAs) and medium-chain fatty acids (MCFAs), critical metabolites that can regulate intestinal physiology and modulate immune functions, as well as serving as energy source for colonocytes or other resident bacteria ( 13 ).…”

Section: Introductionmentioning

confidence: 99%

Effect of ancient wheat pasta on gut microbiota composition and bacteria-derived metabolites: A randomized controlled trial

et al. 2022

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Background and aimIn recent years, many studies have suggested that ancient wheat products might have beneficial effects on cardiometabolic risk profile, but little is known about their effect on gut microbiota (GM). The aim of the present study was to evaluate whether a replacement diet with pasta made from ancient wheat (AD) could influence the GM composition and its metabolites’ production compared to a replacement diet with pasta made from modern wheat (CD).MethodsA randomized, double-blinded crossover trial with two intervention phases was conducted on 20 clinically healthy adults (9 females; 11 males; mean age 43.1 ± 12.5 years). Study participants were assigned to consume pasta made using semi-whole flour from organic wheat that was either from ancient or modern control wheat for 8 weeks in a random order. An 8-week washout period was implemented between the interventions. Stool samples were collected from all subjects at the beginning and at the end of each intervention period. GM composition, and short- (SCFAs) and medium- chain fatty acids (MCFAs) production was evaluated.ResultsDietary interventions did not produce significant diversity in the GM composition at higher ranks (phylum, class, order and family), but only at genus level. In detail, the AD significantly (adj. p < 0.05) changed the abundance of Erysipelatoclostridium spp., Bacteroides_pectinophilus_group spp., CAG-873 spp., and Holdemanella spp. The CD significantly affected the abundance of Akkermansia spp., CAG-873 spp., Hungatella spp., Lachnospiraceae_UCG-008 spp., NK4A214_group spp., Frisingicoccus spp., Megasphaera spp., Synergistes spp., and Tyzzerella spp. Regarding the production of SCFAs and MCFAs, AD resulted in a significant increase of fecal acetic (+0.7%), isobutyric (+30.1%), 2-methylbutyric (+64.2%), and isovaleric (+22.5%) acids. On the other hand, CD resulted in increased levels of isobutyric (+71.4%), 2-methylbutyric (+116.2%), isovaleric (+99%), and valeric (+21.4%) acids, and a reduction of butyric (-31.6%) and hexanoic (-66.4%) acids.ConclusionA short-term replacement diet with both ancient and modern wheat pasta determined significant changes in GM composition at the genus level but notably the AD resulted in a greater beneficial impact on anti-inflammatory SCFAs.

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Bacterial-Based Strategies to Hydrolyze Gluten Peptides and Protect Intestinal Mucosa

Cited by 15 publications

References 38 publications

Multiplex-Competitive ELISA for Detection and Characterization of Gluten during Yogurt Fermentation: Effects of Changes in Certain Fermentation Conditions on Gluten Protein Profiles and Method Reproducibility Assessment

Multiplex-Competitive ELISA for Detection and Characterization of Gluten during Yogurt Fermentation: Effects of Changes in Certain Fermentation Conditions on Gluten Protein Profiles and Method Reproducibility Assessment

Celiac Disease and Possible Dietary Interventions: From Enzymes and Probiotics to Postbiotics and Viruses

Effect of ancient wheat pasta on gut microbiota composition and bacteria-derived metabolites: A randomized controlled trial

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