Exposure of Bifidobacterium longum subsp. infantis to Milk Oligosaccharides Increases Adhesion to Epithelial Cells and Induces a Substantial Transcriptional Response

Kavanaugh, Devon; O’Callaghan, J.R.; Buttó, Ludovica F.; Slattery, Helen; Lane, Jonathan A.; Clyne, Marguerite; Kane, Marian; Joshi, Lokesh; Hickey, Rita M.

doi:10.1371/journal.pone.0067224

Cited by 100 publications

(97 citation statements)

References 57 publications

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“…Chichlowski et al (27) showed that growth of B. infantis ATCC15697 on HMOs increases binding to intestinal epithelial cells in vitro, decreases release of inflammatory cytokines, and increases release of anti-inflammatory cytokines in response to an inflammatory stimulus. A similar increase in binding was determined using sialyllactose (69). These studies suggest that the specific growth phenotype of milk glycan–enriched bifidobacterial populations promotes persistence in situ and positively modulates the host epithelium.…”

Section: Establishing Structure-function Relationships Of Human Milk supporting

confidence: 67%

Breast Milk Oligosaccharides: Structure-Function Relationships in the Neonate

Smilowitz¹,

Lebrilla²,

et al. 2014

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In addition to providing complete postnatal nutrition, breast milk is a complex biofluid that delivers bioactive components for the growth and development of the intestinal and immune systems. Lactation is a unique opportunity to understand the role of diet in shaping the intestinal environment including the infant microbiome. Of considerable interest is the diversity and abundance of milk glycans that are energetically costly for the mammary gland to produce yet indigestible by infants. Milk glycans comprise free oligosaccharides, glycoproteins, glycopeptides, and glycolipids. Emerging technological advances are enabling more comprehensive, sensitive, and rapid analyses of these different classes of milk glycans. Understanding the impact of inter- and intraindividual glycan diversity on function is an important step toward interventions aimed at improving health and preventing disease. This review discusses the state of technology for glycan analysis and how specific structure-function knowledge is enhancing our understanding of early nutrition in the neonate.

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Section: Establishing Structure-function Relationships Of Human Milk supporting

confidence: 67%

Breast Milk Oligosaccharides: Structure-Function Relationships in the Neonate

Smilowitz¹,

Lebrilla²,

et al. 2014

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“…The species that cannot utilize HMOs have a disadvantage and do not readily colonize. However, HMOs do not only serve as substrate for bacteria but they can also enhance Bifidobacteria persistence in the gastrointestinal tract by increasing their ability to bind to epithelial cells (Chichlowski et al 2012;Kavanaugh et al 2013). In the study of Wickramasinghe and collegues (Wickramasinghe et al 2015) it was found that both strain and carbon source affect binding affinity of Bifidobacteria to epithelial cells.…”

Section: Effects Of Hmos On Microbiota Compositionmentioning

confidence: 99%

Non-digestible carbohydrates in infant formula as substitution for human milk oligosaccharide functions: Effects on microbiota and gut maturation

Akkerman

Faas²,

Vos

2018

Critical Reviews in Food Science and Nutrition

130

140

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Human milk (HM) is the golden standard for nutrition of newborn infants. Human milk oligosaccharides (HMOs) are abundantly present in HM and exert multiple beneficial functions, such as support of colonization of the gut microbiota, reduction of pathogenic infections and support of immune development. HMO-composition is during lactation continuously adapted by the mother to accommodate the needs of the neonate. Unfortunately, for many valid reasons not all neonates can be fed with HM and are either totally or partly fed with cow-milk derived infant formulas, which do not contain HMOs. These cow-milk formulas are supplemented with non-digestible carbohydrates (NDCs) that have functional effects similar to that of some HMOs, since production of synthetic HMOs is challenging and still very expensive. However, NDCs cannot substitute all HMO functions. More efficacious NDCs may be developed and customized for specific groups of neonates such as pre-matures and allergy prone infants. Here current knowledge of HMO functions in the neonate in view of possible replacement of HMOs by NDCs in infant formulas is reviewed. Furthermore, methods to expedite identification of suitable NDCs and structure/function relationships are reviewed as in vivo studies in babies are impossible.

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“…First, as described above, B. infantis has a competitive advantage in the presence of human milk components; therefore, increased colonization resulting in decreased diversity of the gut microbiota and fewer luminal pathogens is one likely mechanism of protection. In addition to a selective growth advantage, in vitro studies reveal that B. infantis cells grown on HMO bind to cultured intestinal cells at a higher rate suggesting that the unique ability to grow on HMOs coincides with an increased ability to bind and colonize the intestinal mucus layer (65,66). …”

Section: Mechanisms Of Observed Protective Effectsmentioning

confidence: 99%

Bifidobacterium longum subspecies infantis: champion colonizer of the infant gut

et al. 2014

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Oligosaccharides are abundant in human milk. Production of these highly diverse structures requires significant energy expenditure by the mother and yet these human milk oligosaccharides offer no direct nutritive value to her infant. A primary function of human milk oligosaccharides is to shape the infant’s intestinal microbiota with life-long consequences. Bifidobacterium longum subspecies infantis (B. infantis) is unique among gut bacteria in its prodigious capacity to digest and consume any human milk oligosaccharide structure, the result of a large repertoire of bacterial genes encoding an array of glycosidases and oligosaccharide transporters not found in other bacterial species. In vitro, B. infantis grows better than other bacterial strains in the presence of human milk oligosaccharides, displays anti-inflammatory activity in premature intestinal cells, and decreases intestinal permeability. In premature infants, B. infantis given in combination with human milk increases B. infantis and decreases Enterobacteriaceae in the feces. Probiotics containing B. infantis decrease the risk of necrotizing enterocolitis in premature infants. Colonization with B. infantis is also associated with increased vaccine responses. Probiotic organisms have historically been selected based on ease of production and stability. The advantages of B. infantis, selected through coevolution with human milk glycans, present an opportunity for focused manipulation of the infant intestinal microbiota.

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Exposure of Bifidobacterium longum subsp. infantis to Milk Oligosaccharides Increases Adhesion to Epithelial Cells and Induces a Substantial Transcriptional Response

Cited by 100 publications

References 57 publications

Breast Milk Oligosaccharides: Structure-Function Relationships in the Neonate

Breast Milk Oligosaccharides: Structure-Function Relationships in the Neonate

Non-digestible carbohydrates in infant formula as substitution for human milk oligosaccharide functions: Effects on microbiota and gut maturation

Bifidobacterium longum subspecies infantis: champion colonizer of the infant gut

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