The Weissella and Periweissella genera: up-to-date taxonomy, ecology, safety, biotechnological, and probiotic potential

Fusco, Vincenzina; Chieffi, Daniele; Fanelli, Francesca; Montemurro, Marco; Rizzello, Carlo Giuseppe; Franz, Charles M. A. P.

doi:10.3389/fmicb.2023.1289937

Cited by 3 publications

(3 citation statements)

References 347 publications

(269 reference statements)

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“…Among the Weissella and Periweissella type strains analyzed in this study, only the P. beninensis type was positive in the motility assay, and its many peritrichous and long flagella were visualized via TEM, while, despite the type strains of P. fabalis, P. fabaria and P. ghanensis possessing a complete flagellar operon, no motility was observed in these strains under the conditions used in this study, and only the P. fabaria type strain showed a rudimentary piece of flagellum on few cells. The type strain of P. beninesis showed the highest in vitro adhesion capacity and resistance to simulated gastrointestinal digestion [17] (Fanelli et al, 2023), indicating a possible correlation between the motile behavior and the probiotic potential of this strain.…”

Section: Discussionmentioning

confidence: 98%

“…Species of the genera Weissella and Periweissella are widespread in nature and have been isolated from several food matrices, including meat, fish, vegetables and fermented foods, as well as from soil, sewage and the gastrointestinal tracts of humans and animals [8,9]. Despite their probiotic potential, which has recently been demonstrated by several studies [10,11], to date, none of the Weissella and Periweissella strains are recognized as GRAS (Generally Recognized as Safe) by the Food and Drug Administration (FDA) in the United States of America, nor have they been included in the Qualified Presumption of Safety (QPS) list by the European Food Safety Authority (EFSA).…”

Section: Introductionmentioning

confidence: 99%

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Motility in Periweissella Species: Genomic and Phenotypic Characterization and Update on Motility in Lactobacillaceae

Fanelli,

Montemurro,

Chieffi

et al. 2023

Microorganisms

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The genus Weissella and the recently described genus Periweissella, to which some previously named Weissella species have been reclassified as a result of a taxogenomic assessment, includes lactic acid bacteria species with high biotechnological and probiotic potential. Only one species, namely, Periweissella (P.) beninensis, whose type strain has been shown to possess probiotic features, has so far been described to be motile. However, the availability of numerous genome sequences of Weissella and Periweissella species prompted the possibility to screen for the presence of the genetic determinants encoding motility in Weissella and Periweissellas spp. other than P. beninensis. Herein, we performed a comprehensive genomic analysis to identify motility-related proteins in all Weissella and Periweissella species described so far, and extended the analysis to the recently sequenced Lactobacillaceae spp. Furthermore, we performed motility assays and transmission electron microscopy (TEM) on Periweissella type strains to confirm the genomic prediction. The homology-based analysis revealed genes coding for motility proteins only in the type strains of P. beninensis, P. fabalis, P. fabaria and P. ghanensis genomes. However, only the P. beninensis type strain was positive in the motility assay and displayed run-and-tumble behavior. Many peritrichous and long flagella on bacterial cells were visualized via TEM, as well. As for the Lactobacillaceae, in addition to the species previously described to harbor motility proteins, the genetic determinants of motility were also found in the genomes of the type strains of Lactobacillus rogosae and Ligilactobacillus salitolerans. This study, which is one of the first to analyze the genomes of Weissella, Periweissella and the recently sequenced Lactobacillaceae spp. for the presence of genes coding for motility proteins and which assesses the associated motility phenotypes, provides novel results that expand knowledge on these genera and are useful in the further characterization of lactic acid bacteria.

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Section: Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Motility in Periweissella Species: Genomic and Phenotypic Characterization and Update on Motility in Lactobacillaceae

Fanelli,

Montemurro,

Chieffi

et al. 2023

Microorganisms

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“…Raw milk or thermized/boiled milk may be subjected to (i) natural fermentation, (ii) blackslopping or (iii) adjunct of commercial starter or single/multiple autochthonous microbial cultures. Depending on the raw materials used, the production step, the equipment and the manufacturing environment involved, the metabolic activity of the resulting specific microbiota is responsible for the final textural, sensorial, and probiotic features of each fermented milk and dairy product [28][29][30][31][32][33][34][35][36][37][38][39]. Within the microbiota responsible for the transformation of milk into fermented milk and dairy products, a pivotal role is played by lactic acid bacteria (LABs) while yeasts are arising as important contributors for their technological and probiotic attributes [39].…”

Section: Probiotics In Milk and Milk-derived Productsmentioning

confidence: 99%

Milk and Its Derivatives as Sources of Components and Microorganisms with Health-Promoting Properties: Probiotics and Bioactive Peptides

Quintieri,

Fanelli,

Monaci

et al. 2024

Foods

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Milk is a source of many valuable nutrients, including minerals, vitamins and proteins, with an important role in adult health. Milk and dairy products naturally containing or with added probiotics have healthy functional food properties. Indeed, probiotic microorganisms, which beneficially affect the host by improving the intestinal microbial balance, are recognized to affect the immune response and other important biological functions. In addition to macronutrients and micronutrients, biologically active peptides (BPAs) have been identified within the amino acid sequences of native milk proteins; hydrolytic reactions, such as those catalyzed by digestive enzymes, result in their release. BPAs directly influence numerous biological pathways evoking behavioral, gastrointestinal, hormonal, immunological, neurological, and nutritional responses. The addition of BPAs to food products or application in drug development could improve consumer health and provide therapeutic strategies for the treatment or prevention of diseases. Herein, we review the scientific literature on probiotics, BPAs in milk and dairy products, with special attention to milk from minor species (buffalo, sheep, camel, yak, donkey, etc.); safety assessment will be also taken into consideration. Finally, recent advances in foodomics to unveil the probiotic role in human health and discover novel active peptide sequences will also be provided.

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Weissella cibaria DA2 cell-free supernatant improves the quality of sweet corn kernels during post-harvest storage

Wang,

Jia,

Xue

et al. 2024

Postharvest Biology and Technology

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The Weissella and Periweissella genera: up-to-date taxonomy, ecology, safety, biotechnological, and probiotic potential

Cited by 3 publications

References 347 publications

Motility in Periweissella Species: Genomic and Phenotypic Characterization and Update on Motility in Lactobacillaceae

Motility in Periweissella Species: Genomic and Phenotypic Characterization and Update on Motility in Lactobacillaceae

Milk and Its Derivatives as Sources of Components and Microorganisms with Health-Promoting Properties: Probiotics and Bioactive Peptides

Weissella cibaria DA2 cell-free supernatant improves the quality of sweet corn kernels during post-harvest storage

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