Surface Proteome Analysis of a Natural Isolate of Lactococcus lactis Reveals the Presence of Pili Able to Bind Human Intestinal Epithelial Cells

Meyrand, Mickaël; Guillot, Alain; Goin, Mélodie; Furlan, Sylviane; Armalytė, Julija; Kulakauskas, Saulius; Cortes-Perez, Naima G.; Thomas, G.; Chat, Sophie; Péchoux, Christine; Duprès, Vincent; Hols, Pascal; Dufrêne, Yves F.; Trugnan, Germain; Chapot‐Chartier, Marie‐Pierre

doi:10.1074/mcp.m113.029066

Cited by 63 publications

(87 citation statements)

References 51 publications

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“…Pili were only recently found for members of the Lactococcus genus; however, pilus production is not active during growth in standard laboratory culture medium (40). Pili were also shown to facilitate L. lactis attachment to intestinal epithelial Caco-2 cells (61), and this capacity might also be important for binding to plant tissues. One of the pilus-associated proteins possessing a lectin domain (open reading frame 4 [ORF4]) was putatively designated to be responsible for epithelial cell binding (61).…”

Section: Discussionmentioning

confidence: 99%

“…Pili were also shown to facilitate L. lactis attachment to intestinal epithelial Caco-2 cells (61), and this capacity might also be important for binding to plant tissues. One of the pilus-associated proteins possessing a lectin domain (open reading frame 4 [ORF4]) was putatively designated to be responsible for epithelial cell binding (61). In KF147, the ATL-inducible gene ywfG (llkf_2426) encodes a putative LPXTG-anchored mucus binding protein with a lectin domain that might provide a similar function for L. lactis on plants.…”

Section: Discussionmentioning

confidence: 99%

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Lactococcus lactis Metabolism and Gene Expression during Growth on Plant Tissues

Golomb

Marco

2014

J. Bacteriol.

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Lactic acid bacteria have been isolated from living, harvested, and fermented plant materials; however, the adaptations these bacteria possess for growth on plant tissues are largely unknown. In this study, we investigated plant habitat-specific traits of Lactococcus lactis during growth in an Arabidopsis thaliana leaf tissue lysate (ATL). L. lactis KF147, a strain originally isolated from plants, exhibited a higher growth rate and reached 7.9-fold-greater cell densities during growth in ATL than the dairy-associated strain L. lactis IL1403. Transcriptome profiling (RNA-seq) of KF147 identified 853 induced and 264 repressed genes during growth in ATL compared to that in GM17 laboratory culture medium. Genes induced in ATL included those involved in the arginine deiminase pathway and a total of 140 carbohydrate transport and metabolism genes, many of which are involved in xylose, arabinose, cellobiose, and hemicellulose metabolism. The induction of those genes corresponded with L. lactis KF147 nutrient consumption and production of metabolic end products in ATL as measured by gas chromatography-time of flight mass spectrometry (GC-TOF/MS) untargeted metabolomic profiling. To assess the importance of specific plant-inducible genes for L. lactis growth in ATL, xylose metabolism was targeted for gene knockout mutagenesis. Wild-type L. lactis strain KF147 but not an xylA deletion mutant was able to grow using xylose as the sole carbon source. However, both strains grew to similarly high levels in ATL, indicating redundancy in L. lactis carbohydrate metabolism on plant tissues. These findings show that certain strains of L. lactis are well adapted for growth on plants and possess specific traits relevant for plant-based food, fuel, and feed fermentations. L actic acid bacteria (LAB) found on plants are essential for the production of a wide variety of plant-derived fermented foods with desirable organoleptic properties, improved nutritional attributes, and extended shelf life (1). LAB are a diverse group of bacterial species in the Firmicutes phylum that are characterized by the production of lactic acid as the main end product of carbohydrate metabolism. Some of the most commonly recognized genera among the LAB include Lactococcus, Lactobacillus, Leuconostoc, Pediococcus, and Oenococcus. LAB-fermented plantbased food products include sauerkraut, sourdough, and olives, as well as diverse foods unique to different ethnic groups (e.g., pulque, nukadoko, or gundruk [2,3]). LAB are responsible for the conversion of plant tissues such as alfalfa into silage for animal feed with enhanced nutritional content and stability (4). LAB are also used to ferment plant-based substrates into industrial-grade lactic acid for the manufacture of polylactide bioplastics (5). Conversely, LAB are frequent contaminants of bioethanol fermentations (6).In contrast to commercial dairy fermentations that utilize starter cultures, initiation of plant-based fermentations typically relies on the LAB that are located on or associated with plant tis...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Lactococcus lactis Metabolism and Gene Expression during Growth on Plant Tissues

Golomb

Marco

2014

J. Bacteriol.

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“…The mucus-binding ability of L. rhamnosus GG is conferred by the pilus-associated SpaC, present along the length of the pilus shaft potentially resulting in the prolonged residency of L. rhamnosus GG in the GI tract (Kankainen et al, 2009;Reunanen et al, 2012). More recently pili have also been implicated in GI colonization and persistence of Bifidobacteria in the murine gut (O'Connell Motherway et al, 2011;Turroni et al, 2013) and in bacterial autoaggregation and biofilm formation of Lactococcus lactis in vitro (Oxaran et al, 2012;Meyrand et al, 2013). These appendages that decorate the bacterial surface are increasingly considered as key molecules in mediating bacterial adherence to the host epithelium and in influencing mucosal immune responses.…”

Section: Discussionmentioning

confidence: 99%

“…Although the adhesive abilities of enteropathogenic bacteria have been extensively studied, the systems responsible for intestinal adhesion of gut commensal and probiotic bacteria to mucus are poorly understood. High-throughput sequencing of Lactobacillus genomes provides a platform for functional analysis of genes that may contribute to adhesion and probiotic function (Pridmore et al, 2004;Pfeiler and Klaenhammer, 2007;Ventura et al, 2009;Turpin et al, 2012;Meyrand et al, 2013). A growing number of reports indicate that LPXTGanchored cell wall proteins with modular domain organization, such as L. reuteri MUB, function in the adherence of probiotic strains to the host intestinal mucosa (Kleerebezem et al, 2010;Walter et al, 2011;Call and Klaenhammer, 2013).…”

Section: Discussionmentioning

confidence: 99%

Structural basis for adaptation of lactobacilli to gastrointestinal mucus

Etzold

Kober

MacKenzie

et al. 2014

Environmental Microbiology

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SummaryThe mucus layer covering the gastrointestinal (GI) epithelium is critical in selecting and maintaining homeostatic interactions with our gut bacteria. However, the underpinning mechanisms of these interactions are not understood. Here, we provide structural and functional insights into the canonical mucus-binding protein (MUB), a multi-repeat cellsurface adhesin found in Lactobacillus inhabitants of the GI tract. X-ray crystallography together with small-angle X-ray scattering demonstrated a 'beads on a string' arrangement of repeats, generating 174 nm long protein fibrils, as shown by atomic force microscopy. Each repeat consists of tandemly arranged Ig-and mucin-binding protein (MucBP) modules. The binding of full-length MUB was confined to mucus via multiple interactions involving terminal sialylated mucin glycans. While individual MUB domains showed structural similarity to fimbrial proteins from Gram-positive pathogens, the particular organization of MUB provides a structural explanation for the mechanisms in which lactobacilli have adapted to their host niche by maximizing interactions with the mucus receptors, potentiating the retention of bacteria within the mucus layer. Together, this study reveals functional and structural features which may affect tropism of microbes across mucus and along the GI tract, providing unique insights into the mechanisms adopted by commensals and probiotics to adapt to the mucosal environment.

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“…Recently the key adhesion protein of the L. rhamnosus GG pilus, SpaC has been demonstrated to show strong binding with two extracellular proteins i.e .mucin and collagen as well as promote bacterial aggregation phenomenon [54]. Similarly, the strong adhesion ability has been shown by the pili of L. lactis to intestinal epithelial cells (Caco-2) [55]. Therefore, in a nut shell, as surface protruding molecules they play vital role in the adhesion of probiotic species to their respective host cells and promotes immuno-modulatory functions.…”

Section: Pilli Fimbriae and Flagellamentioning

confidence: 99%

Metabiotics: The Functional Metabolic Signatures of Probiotics: Current State-of-Art and Future Research Priorities—Metabiotics: Probiotics Effector Molecules

Singh¹,

Vishwakarma²,

Singhal³

2018

ABB

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The intricate "orchestered molecular conversation" between the host and gut microbiome is one of the most dynamic research areas in recent years. The rhythmic chemical cross talk in the form of bioactive metabolites and signalling molecules synthesized by gut microbiome plays a significant role for the modulation of human health in diversified ways. They are recognized as low molecular weight (LMW) molecules having versatile chemical attributes. They possess magnificent capability of interacting with surrounding environment and controlling the genes for various genetic, biochemical and physiological functions for maintaining the homeostasis that is now-a-days termed as "small molecules microbes originated (SMOM) homeostasis" in the host. These metabolic signatures have close structural and functional resemblance with small molecules synthesized by host eukaryotic cells and dietary components. Therefore, they may be considered as universalized metabolites contributing to the remarkable phenomenon of epigenetic regulation, cell to cell communication and stability of genome manifesting the overall growth and development of the host and known as "metabiotics". The wide panorama of utilization of probiotics is continuously expanding and conferring the major health benefits through metabiotic components are gaining tremendous momentum therefore recognized as "hidden soldiers" of the body. Therefore firstly, we outline the need and types of metabiotic molecules and depicting their role in human health. Then, we summarize their preventive and therapeutic avenues in various diseases and finally, we propose the current technological interventions, bottlenecks and future perspectives in this field that are implied for accelerating their comprehensive understanding and utilization at industrial scale.

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Surface Proteome Analysis of a Natural Isolate of Lactococcus lactis Reveals the Presence of Pili Able to Bind Human Intestinal Epithelial Cells

Cited by 63 publications

References 51 publications

Lactococcus lactis Metabolism and Gene Expression during Growth on Plant Tissues

Lactococcus lactis Metabolism and Gene Expression during Growth on Plant Tissues

Structural basis for adaptation of lactobacilli to gastrointestinal mucus

Metabiotics: The Functional Metabolic Signatures of Probiotics: Current State-of-Art and Future Research Priorities—Metabiotics: Probiotics Effector Molecules

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