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Human milk oligosaccharides – the plot thickens

Published online by Cambridge University Press:  15 December 2008

Sharon M. Donovan*
Affiliation:
Department of Food Science and Human Nutrition, University of Illinois, 457 Bevier Hall, 905 S. Goodwin Avenue, Urbana, IL 61801, [email protected]
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Extract

Human milk is a complex physiological fluid that provides nutrients as well as bioactive factors for the infant(1). A distinctive property of human milk among all other species is its remarkable content and structural diversity of oligosaccharides(24).

Type
Invited Commentary
Copyright
Copyright © The Author 2008

Human milk is a complex physiological fluid that provides nutrients as well as bioactive factors for the infant(Reference Donovan1). A distinctive property of human milk among all other species is its remarkable content and structural diversity of oligosaccharides(Reference Bode2Reference German, Freeman and Lebrilla4). A broad range of functions has been attributed to human milk oligosaccharides (HMO), including serving as a component of the innate immunity of human milk by preventing attachment of potential pathogens to the intestinal lining(Reference Newburg, Ruiz-Palacios and Morrow5, Reference Morrow, Ruiz-Palacios and Jiang6) and by serving as a prebiotic to promote colonization by a healthy gut microbiota(Reference Bode2Reference German, Freeman and Lebrilla4). HMO are resistant to digestion(Reference Chaturvedi, Warren and Buescher7), thus little focus had been placed on the potential impact of HMO on the host epithelial cells. However, two recent articles published in the British Journal of Nutrition by Kuntz et al. (Reference Kuntz, Rudloff and Kunz8, Reference Kuntz, Kunz and Rudloff9) provide compelling evidence that HMO modulate intestinal cell proliferation, differentiation and apoptosis via receptor binding and MAP-kinase signalling. These reports provide novel insight into a new contribution of HMO to neonatal intestinal development.

HMO are the third most predominant component in human milk after lactose and lipid, averaging about 20 g/l in colostrum and 5–10 g/l in mature milk(Reference Chaturvedi, Warren and Altaye10, Reference Coppa, Pierani and Zampini11). HMO differ in molecular weight and structure, constituent sugar or sugar derivatives and pH(Reference Kunz, Rudloff and Baier3). They are composed of both neutral and anionic components. HMO are synthesized in the mammary gland with a lactose core at the reducing end and elongation by N-acetyllactosamine units, with greater structural diversity provided by extensive fucosylation and/or sialylation wherein fucose and sialic acid residues are added at the terminal positions(Reference Bode2Reference German, Freeman and Lebrilla4). HMO vary in size from three to thirty-two sugars(Reference German, Freeman and Lebrilla4) and consist of linear and branched polymers linked together by at least twelve different types of glycosidic bonds(Reference Kunz, Rudloff and Baier3). Current analytical methods have detected approximately 200 distinct molecular species of HMO consisting of mostly neutral and fucosylated oligosaccharides(Reference German, Freeman and Lebrilla4, Reference Niñonuevo, Park and Yin12).

HMO differ among women and four phenotypic groups, consistent with the Lewis blood group system, have been recognized based on the expression and activity of two fucosyltransferases(Reference Stahl, Thurl and Henker13). The HMO components were recently identified in five donors by microfluidic chips and MS(Reference Niñonuevo, Perkins and Francis14). The dominant oligosaccharides components were lacto-N-tetraose (LNT), lacto-N-neotetraose and lacto-N-fucopentaose I/V. A neutral oligosaccharide with neutral mass 709.3 Da (3Hex, 1HexNAc–LNT) was the most prominent oligosaccharide that was present in all human milk samples(Reference Niñonuevo, Perkins and Francis14). Consistent with the bifidogenic activity of HMO, this HMO has been previously shown to be preferentially fermented by Bifidobacterium longum biovar infantis, an isolate from the infant gut(Reference LoCascio, Niñonuevo and Freeman15, Reference Ward, Niñonuevo and Mills16). The next most common species with relatively strong abundances consisted of neutral fucosylated oligosaccharides and a fucosylated species with a sialic acid residue.

HMO resist digestion within the stomach and intestine and a significant proportion of HMO passes into the lower gastrointestinal tract(Reference Chaturvedi, Warren and Buescher7), where they are selectively metabolized by beneficial micro-organisms. The bifidogenic potential of HMO is frequently cited as an important reason why the gastrointestinal microbiota of breast-fed infants contains proportionally more bifidobacteria than that of formula-fed infants(Reference Harmsen, Wildeboer-Veloo and Raangs17). To gain insight into the mechanisms underlying the bifidogenic properties of human milk, the transcriptome of B. longum LMG 13 197 grown in human milk or formula containing galacto-oligosaccharides and long-chain fructo-oligosaccharides was compared with each other and with bacteria grown on glucose-containing media(Reference Gonzalez, Klaassens and Malinen18). Common genes that were highly up-regulated by both human milk and formula included putative genes for cell surface type 2 glycoprotein-binding fimbriae, which are implicated in attachment and colonization in the intestine(Reference Gonzalez, Klaassens and Malinen18). Genes involved in carbohydrate metabolism formed the dominant group specifically up-regulated in breast milk and included putative genes for N-acetylglucosamine degradation and for metabolism of mucin and HMO via the galactose/lacto-N-biose gene cluster(Reference Gonzalez, Klaassens and Malinen18). Thus, HMO exert bifidogenic properties by serving as a fermentable substrate(Reference LoCascio, Niñonuevo and Freeman15, Reference Ward, Niñonuevo and Mills16) and, in turn, modulate the bacterium's transcriptome to support its catalytic activity. Indeed, the genomic sequence of bifidobacterium revealed 700 genes that are unique to B. longum infantis, relative to other bifidobacterium including a variety of co-regulated glycosidases, suggesting a co-evolution of this strain of bifidobacterium to be uniquely suited for colonization of the human milk-fed infant(Reference German, Freeman and Lebrilla4).

Certain HMO share common epitopes to those present on the infant's intestinal epithelia and known receptors for pathogens and, thus, act as decoys to prevent binding of pathogens to the epithelial cells(Reference Newburg, Ruiz-Palacios and Morrow5, Reference Morrow, Ruiz-Palacios and Jiang6, Reference Kunz and Rudloff19). The significant immunological protection afforded by HMO has been partly attributed to the presence of α(1–2)-linked fucosylated oligosaccharides(Reference Morrow, Ruiz-Palacios and Jiang6). Fucosylated oligosaccharides are capable of preventing diarrhoeal illness through diverse mechanisms, including inhibition of Escherichia coli activity by binding and blocking access to target receptors, prevention of Campylobacter adhesion to intestinal cells and competitive inhibition of the binding of Norovirus to the intestinal epithelium(Reference Newburg, Ruiz-Palacios and Morrow5).

Last, HMO also can be absorbed into the circulatory system and are excreted in the urine of breast-fed infants(Reference Rudloff, Pohlentz and Diekmann20). HMO are transported via the circulation to other sites, such as the urinary tract, where they are thought to block pathogen adhesion(Reference Chaturvedi, Warren and Buescher7, Reference Rudloff, Pohlentz and Diekmann20). HMO have structural similarities to selectin ligands, which mediate important cell–cell interactions in the immune system. Leucocyte infiltration into tissues is associated with many inflammatory conditions. Acidic HMO inhibited rolling and adhesion of leucocytes isolated from human blood to cultured human umbilical vein endothelial cells in a concentration-dependent manner(Reference Bode, Kunz and Muhly-Reinholz21). Furthermore, Bode et al. (Reference Bode, Rudloff and Kunz22) demonstrated that acidic (sialic-containing) HMO, but not neutral HMO, serve as anti-inflammatory components by inhibiting the formation of platelet–neutrophil complexes (PNC) and neutrophil activation. These findings support a role for HMO anti-inflammatory factors which may contribute to the lower incidence and severity of inflammatory diseases in breast-fed infants(Reference Kunz and Rudloff19, Reference Bode, Kunz and Muhly-Reinholz21, Reference Bode, Rudloff and Kunz22).

In a study published earlier this year in the British Journal of Nutrition, Kuntz et al. (Reference Kuntz, Rudloff and Kunz8) tested the hypothesis that HMO would affect intestinal epithelial cell dynamics. Effects of isolated acidic HMO and neutral HMO fractions or individual oligosaccharides on proliferation, differentiation and apoptosis were assessed in preconfluent transformed human intestinal cells (HT-29 and Caco-2) and non-transformed small-intestinal epithelial crypt cells of fetal origin (HIEC). Growth inhibition was induced by neutral and acidic HMO fractions in all cell lines in a dose-dependent manner. However, transformed cell lines (HT-29 and Caco-2 cells) were more sensitive than HIEC cells. In contrast, HMO induced differentiation (alkaline phosphatase activity) in HT-29 and HIEC cells, but not Caco-2 cells. Among individual oligosaccharides, only sialyllactoses induced differentiation. Induction of apoptosis was also detected in HT-29 and HIEC cells, but for neutral oligosaccharides, not for acidic fractions. Thus, for the first time, acidic and neutral HMO were shown to induce growth inhibition in intestinal cells through at least two different mechanisms, by suppressing cell cycle progression through the induction of differentiation and/or by influencing apoptosis(Reference Kuntz, Rudloff and Kunz8).

To further elucidate the underlying molecular mechanisms of action of HMO on cell cycle dynamics, in a study published in this issue of the British Journal of Nutrition, Kuntz et al. (Reference Kuntz, Kunz and Rudloff9) exposed HT-29, HIEC and Caco-2 cells to neutral or acidic HMO and investigated cell cycle events via flow cytometry and expression levels of cell cycle regulators by using quantitative real-time RT-PCR. Consistent with their previous study(Reference Kuntz, Kunz and Rudloff9), both acidic and neutral fractions induced a concentration-dependent decrease in proliferation, which was evidenced by G2/M-arrest and associated changes in cyclin A and B mRNA expression. In addition, they observed that the expression of the cyclin-dependent kinase inhibitors p21cip1 and p27kip1p21cip1 was p53-independent and necessary for arresting cells in the G2/M phase, while p27kip1 was associated with differentiation effects. Lastly, both neutral and acidic HMO induced phosphorylation of the epidermal growth factor receptor and stimulated the MAP-kinase signalling pathway (ERK1/2 and p38 phosphorylation)(Reference Kuntz, Kunz and Rudloff9).

Further studies are needed to determine the mechanism(s) whereby HMO are able to stimulate EGFR signalling and whether these effects can be blocked by specific inhibitors of EGFR- and p38-signalling pathways. In addition, the potential physiological relevance of these in vitro observations should be established by translation to preclinical animal models to determine whether HMO affect intestinal cell dynamics within the complex milieu of the gastrointestinal tract.

References

1 Donovan, SM (2006) Role of human milk components in gastrointestinal development: current knowledge and future needs. J Pediatr 149, Suppl., S49S61.CrossRefGoogle Scholar
2 Bode, L (2006) Recent advances on structure, metabolism, and function of human milk oligosaccharides. J Nutr 136, 21272130.CrossRefGoogle ScholarPubMed
3 Kunz, C, Rudloff, S, Baier, W, et al. . (2000) Oligosaccharides in human milk: structural, functional, and metabolic aspects. Annu Rev Nutr 20, 699722.CrossRefGoogle ScholarPubMed
4 German, J, Freeman, S, Lebrilla, C, et al. . (2008) Human milk oligosaccharides: evolution, structures and bioselectivity as substrates for intestinal bacteria. Nestle Nutr Workshop Ser Pediatr Program 62, 205222.CrossRefGoogle ScholarPubMed
5 Newburg, DS, Ruiz-Palacios, GM & Morrow, AL (2005) Human milk glycans protect infants against enteric pathogens. Annu Rev Nutr 25, 3758.CrossRefGoogle ScholarPubMed
6 Morrow, AL, Ruiz-Palacios, GM, Jiang, X, et al. . (2005) Human-milk glycans that inhibit pathogen binding protect breast-feeding infants against infectious diarrhea. J Nutr 135, 13041307.CrossRefGoogle ScholarPubMed
7 Chaturvedi, P, Warren, CD, Buescher, CR, et al. . (2001) Survival of human milk oligosaccharides in the intestine of infants. Adv Exp Med Biol 501, 315323.CrossRefGoogle ScholarPubMed
8 Kuntz, S, Rudloff, S & Kunz, C (2008) Oligosaccharides from human milk influence growth-related characteristics of intestinally transformed and non-transformed intestinal cells. Br J Nutr 99, 462471.CrossRefGoogle ScholarPubMed
9 Kuntz, S, Kunz, C & Rudloff, S (2009) Oligosaccharides from human milk induce growth arrest via G2/M by influencing growth-related cell cycle genes in intestinal epithelial cells. Br J Nutr 101, 13061315.CrossRefGoogle ScholarPubMed
10 Chaturvedi, P, Warren, CD, Altaye, M, et al. . (2001) Fucosylated human milk oligosaccharides vary between individuals and over the course of lactation. Glycobiology 11, 365372.CrossRefGoogle ScholarPubMed
11 Coppa, GV, Pierani, P, Zampini, L, et al. . (1999) Oligosaccharides in human milk during different phases of lactation. Acta Paediatr Suppl 88, 8994.CrossRefGoogle ScholarPubMed
12 Niñonuevo, MR, Park, Y, Yin, H, et al. (2006) A strategy for annotating the human milk glycome. J Agric Food Chem 54, 74717480.CrossRefGoogle ScholarPubMed
13 Stahl, B, Thurl, S, Henker, J, et al. . (2001) Detection of four human milk groups with respect to Lewis-blood-group dependent oligosaccharides by serologic and chromatographic analysis. Adv Exp Med Biol 501, 299306.CrossRefGoogle ScholarPubMed
14 Niñonuevo, MR, Perkins, PD, Francis, J, et al. . (2008) Daily variations in oligosaccharides of human milk determined by microfluidic chips and mass spectrometry. J Agric Food Chem 56, 618626.CrossRefGoogle ScholarPubMed
15 LoCascio, RG, Niñonuevo, MR, Freeman, SL, et al. . (2007) Glycoprofiling of bifidobacterial consumption of human milk oligosaccharides demonstrates strain specific, preferential consumption of small chain glycans secreted in early human lactation. J Agric Food Chem 55, 89148919.CrossRefGoogle ScholarPubMed
16 Ward, RE, Niñonuevo, M, Mills, DA, et al. . (2007) In vitro fermentability of human milk oligosaccharides by several strains of bifidobacteria. Mol Nutr Food Res 51, 13981405.CrossRefGoogle ScholarPubMed
17 Harmsen, HJ, Wildeboer-Veloo, AC, Raangs, GC, et al. . (2000) Analysis of intestinal flora development in breast-fed and formula-fed infants by using molecular identification and detection methods. J Pediatr Gastroenterol Nutr 30, 6167.Google ScholarPubMed
18 Gonzalez, R, Klaassens, ES, Malinen, E, et al. . (2008) Differential transcriptional response of Bifidobacterium longum to human milk, formula milk, and galactooligosaccharide. Appl Environ Microbiol 74, 46864694.CrossRefGoogle ScholarPubMed
19 Kunz, C & Rudloff, S (2008) Potential anti-inflammatory and anti-infectious effects of human milk oligosaccharides. Adv Exp Med Biol 606, 455465.CrossRefGoogle ScholarPubMed
20 Rudloff, S, Pohlentz, G, Diekmann, L, et al. . (1996) Urinary excretion of lactose and oligosaccharides in preterm infants fed human milk or infant formula. Acta Pediatr 85, 598603.CrossRefGoogle ScholarPubMed
21 Bode, L, Kunz, C, Muhly-Reinholz, M, et al. . (2004) Inhibition of monocyte, lymphocyte and neutrophil adhesion to endothelial cells by human milk oligosaccharides. J Leukoc Biol 76, 820826.CrossRefGoogle Scholar
22 Bode, L, Rudloff, S, Kunz, C, et al. . (2004) Human milk oligosaccharides reduce platelet-neutrophil complex formation leading to a decrease in neutrophil β 2 integrin expression. Thromb Haemost 92, 14021410.CrossRefGoogle Scholar