3% and 0.02%, respectively, Figure 4). Also, the similar proportion of Firmicutes in human milk compared to selleck chemicals llc mothers’ feces (34.6% and 59.6%, respectively, Figure 4) correlates with the hypothesis that mothers’ milk may be inoculated by immune cells carrying bacteria from the GI tract of the mother to her breast [37–39]. This may be a mechanism by which
the human milk microbiome is shaped by the general health of the mother, including her weight [20]. Functionality of the human milk metagenome Using Illumina sequencing of all DNA within milk samples permits the prediction of ORFs within assembled contigs and allows for determination of the functional capability of the milk metagenome. A total of 41,352 ORFs were predicted, including those for basic cell function, as well as MAPK inhibitor those that may enable the bacteria to remain in human milk, such as ORFs for carbohydrate VS-4718 metabolism (5.7% of ORFs, Figure 3). The predominant carbohydrate in human milk, lactose, is a potential carbon source for human milk bacteria, and therefore the presence of ORFs associated
with its metabolism (6.7% of carbohydrate-associated metabolism, Figure 3) is expected. Another carbon source for bacteria in human milk is human milk oligosaccharides (HMOs), which cannot be digested by the infant [40]. These oligosaccharides, which are heavily fucosylated and readily digested by Bifidobacteria, are thought to be responsible for the colonization of BF-infants with high levels of Bifidobacteria[41]. Due to a lack of contigs aligning to Bifidobacteria (Figure 2), no ORFs encoding genes for HMOs were observed (Figure 3). Recently, HMOs have also been correlated with increased abundance of Staphylococcus within human milk, regardless of their inability to utilize the human milk oligosaccharides as a carbon source [42]. The predominance of Staphylococcus-aligning contigs in our milk samples supports these findings (Figure 2). Furthermore, there was a Liothyronine Sodium significantly higher number of ORFs related to nitrogen metabolism within the human milk metagenome
in comparison to BF- and FF-infants’ feces (Figure 5, P < 0.05). Because human milk contains 1.48-2.47 g of nitrogen per 100 g of milk, the bacteria within human milk may use it as a nutrient source in addition to lactose and HMOs [43]. Human milk contains an abundance of immune cells, antibodies and antimicrobial proteins (such as lactoferrin, CD14, alpha-lactalbumin, and lysozyme), and therefore the bacteria residing within human milk must harbor mechanisms to combat the milk-endogenous immune system [44–46]. For example, the metagenome of human milk includes ORFs for stress response and defense (4.0% and 4.5% of all ORFs, respectively) including those for oxidative stress (40.3% of stress-related ORFs) and toxic compound resistance (60.2% of defense ORFs, Figure 3).