Monthly Archives: February 2013
Breast milk, besides being very nutritious, provides bioactive constituents that favor the development of the infant immune system and prevent diseases. From this point of view, the best known compounds are maternal immunoglobulins, immunocompetent cells and various antimicrobials. It also contains prebiotic substances, ie, several molecules such as oligosaccharides, which stimulate the growth of specific bacteria in the gut of the child.
However, other important constituents of breast milk, unsuspected until few years ago, are the bacteria. In fact, milk is not sterile, it contains microorganisms, primarily beneficial bacteria that help to establish the intestinal microbiota of the newborn, and which are the first to settle there. Although artificial milk are made to resemble the breast milk, they remain distinct and do not contain bacteria. And for this reason, the intestinal microbiota of breast-fed infants is different than those fed with artificial breast milk.
Lactobacilli (image from AJC1Flickr) and suckling baby (© Photos.com)
Just a few weeks ago was published a work ( Cabrera-Rubio et al., 2012 ) in the American Journal of Clinical Nutrition that had a good coverage in media, blogs and networks ( click here for an example), because it shows the great diversity of bacteria present in the breast milk.
Although this work done by Valencian researchers (Cavanilles Institute, University of Valencia and CSIC-IATA) with Finnish researchers is not the first study that examines this issue, this study shows that bacteria are from very diverse species.
One of the novelties of this paper is the method used, taking advantage of the latest molecular biology: they studied the microbiome in breast milk, that is, the analysis of all possible bacteria present in the samples, by DNA sequencing, without the traditional isolation of living bacteria in plates. To do so, from the aseptically collected milk, DNA is extracted and the gene fragments of bacterial 16S rRNA are amplified by PCR. These amplified genes are sequenced by pyrosequencing (454 Roche GS-FLX), the most innovative and rapid sequencing technology: a machine of this allows about 400 million base pairs (bp) of DNA in 10 hours. From the rRNA gene of each possible bacteria some 500 bp are sequenced. Thus, in this study about 120,000 sequences have been analyzed, corresponding to 2600 sequences per milk sample.
By comparing these sequences with the databases and applying statistical methods conclusions can be drawn on what taxonomic groups (genera and species) bacteria are present and in what proportion.
Predominant genera of bacteria in breast milk (Cabrera-Rubio et al., 2012)
As shown in the figure above, Cabrera et al. found in the milk of healthy mothers that the predominant genera are Leuconostoc, Weissella, Lactococcus and Staphylococcus, of which the first three are lactic acid bacteria. Although these are predominant in colostrum and milk during the first months, then other bacteria are increasing their numbers, such as Veillonella Leptotrichia (anaerobic gram-negative bacteria), which are typical commensal of the oral cavity. In total, about 1000 species have been found, that vary depending on the mother. Curiously, there are significant variations on whether delivery had been vaginal or cesarean, and on the obesity of the mother. The reasons for this are not yet clear.
And where the bacteria in breast milk come from ?
Besides the identifications made in this study of Cabrera et al. (2012) on the basis of DNA present, it has been observed by making viable counts that the total number of bacteria in breast milk is between 2·104 and 3·105 per ml (Juan Miguel Rodríguez), that is, a quantity not negligible . What is its origin?
The study of the microbiome of Cabrera et al. also concluded that the composition of different bacteria is somewhat different from that of other bacterial communities in the human body (the human bacterial niches: skin, mouth, digestive system, vagina, etc), and therefore the milk microbiome is not a particular subset of one of these niches.
The group Probilac from Universidad Complutense de Madrid, whose head is Juan Miguel Rodriguez, a friend and colleague of Red BAL (Spanish network of lactic acid bacteria) is working in this area for years (ex: Martin et al 2003 , Martin et al 2004).
As discussed in a recent review published by this group (Fernández et al 2012), the bacteria present in the breast milk would come from three possible sources (figure below): skin bacteria from the same breast, the oral cavity of the infant, and the most surprising, commensal bacteria of the maternal gut that pass to milk by the entero-mammary pathway.
Potential sources of bacteria present in human colostrum and milk, including the transit of intestinal commensal bacteria to the milk by the entero-mammary pathway (Fernández et al., 2012). DC: dendritic cells.
Indeed, several studies had shown that dendritic cells cross the intestinal epithelium (between enterocytes) and may take commensal bacteria of the gut lumen, incorporating them by endocytosis, but keeping them alive. See details in the following diagram.
Dendritic cell capturing gut bacteria (Scheme of J.M. Rodríguez, group Probilac, Univ. Complutense de Madrid).
These dendritic cells travel through the circulatory system, reaching the mammary glands, where it seems that include bacteria to milk. This is the the entero-mammary pathway.
In this breast microbiota, bacteria from breast skin and from oral cavity of the child also would be incorporated. Some of these bacteria the child’s oral cavity are actually related to those of its gastrointestinal tract. As the first bacteria inhabiting this tract are those of the vaginal microbiota during birth (and intestinal if delivery is cesarean), this would explain the phylogeny of certain bacteria in the milk of these microbiota.
In summary, we see as the “good” bacteria (lactic acid bacteria, but also bifidobacteria and other) from maternal gut, by different ways, arrive to breast milk, and the reach the child’s gut, developing there the child’s microbiota, and helping to complete the neonatal immune system.
Cabrera-Rubio R, MC Collado, K Laitinen, S Salminen, E Isolauri, A Mira (2012) The human milk microbiome changes over lactation and is shaped by maternal weight and mode of delivery. American J Clinical Nutrition 96, 544–51
Grupo Probilac (Juan Miguel Rodríguez Gómez) Microbiota de la leche humana en condiciones fisiológicas: http://www.ucm.es/info/probilac/microbiota2.htm, Departamento de Nutrición, Bromatología y Tecnología de los Alimentos, Facultad de Veterinaria, Universidad Complutense de Madrid
Fernández L, S Langa, V Martín, A Maldonado, E Jiménez, R Martín, JM Rodríguez (2012) The human milk microbiota: Origin and potential roles in health and disease. Pharmacological Research http://dx.doi.org/10.1016/j.phrs.2012.09.001
Hunt KM JA Foster, LJ Forney, UME Schütte, DL Beck, Z Abdo, LK Fox, JE Williams, MK McGuire, MA McGuire (2011) Characterization of the diversity and temporal stability of bacterial communities in human milk. PLoS ONE 6:e21313.
Martín R, S Langa, C Revriego, E Jiménez, ML Marín, J Xaus, L Fernández, JM Rodríguez (2003) Human milk is a source of lactic acid bacteria for the infant gut. J Ped. 143, 754-758.
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