Abstract

The microbiota of human breast milk (HBM) contribute to infant gut colonization; however, whether bacterial extracellular vesicles (EVs) are present in HBM or might contribute to this process remains unknown. In this study, we characterized the HBM microbiota of healthy Korean mothers and measured the key bacteria likely affecting infant gut colonization by analyzing both the microbiota and bacterial EVs. A total of 22 HBM samples were collected from lactating mothers. The DNA of bacteria and bacteria-derived EVs was extracted from each sample. In alpha-diversity analyses, bacterial samples showed higher richness and evenness than bacterial EV samples, and beta-diversity analyses showed significant differences between bacteria and bacterial EVs within identical individual samples. Firmicutes accounted for the largest proportion among the phyla, followed by Proteobacteria, Bacteroidetes, and Actinobacteria, in both bacteria and bacterial EV samples. At the genus level, Streptococcus (25.1%) and Staphylococcus (10.7%) were predominant in bacterial samples, whereas Bacteroides (9.1%), Acinetobacter (6.9%), and Lactobacillaceae(f) (5.5%) were prevalent in bacterial EV samples. Several genera, including Bifidobacterium, were significantly positively correlated between the two samples. This study revealed the diverse bacterial communities in the HBM of healthy lactating mothers, and found that gut-associated genera accounted for a high proportion in bacterial EV samples. Our findings suggest the existence of key bacteria with metabolic activity that are independent of the major bacterial populations that inhabit HBM, and the possibility that EVs derived from these bacteria are involved in the vertical transfer of gut microbiota.

Gut bacteria: Analysing transfer from mother to child

Human breast milk contains a diverse population of bacteria, and tiny membrane-bound packages called extracellular vesicles (EVs) released by bacteria, both of which may contribute to the establishment of beneficial bacterial populations in the infant gut. The microbes that live naturally in our gut are believed to be involved in the development of a healthy immune system, as well as supporting digestion and influencing other aspects of health. Su Yeong Kim and Dae Yong Yi at Chung-Ang University Hospital in Seoul, South Korea, performed a detailed analysis of DNA from bacteria and EVs in breast milk produced by healthy mothers. In addition to categorising the diverse bacterial populations, the study confirms the presence of EVs in human breast milk. These EVs may influence the transmission of bacteria from the mother into an infant’s gut.