microRNA as a new immune-regulatory agent in breast milk - PubMed (original) (raw)

microRNA as a new immune-regulatory agent in breast milk

Nobuyoshi Kosaka et al. Silence. 2010.

Abstract

Background: Breast milk is a complex liquid that provides nutrition to the infant and facilitates the maturation of the infant's immune system. Recent studies indicated that microRNA (miRNA) exists in human body fluid. Because miRNAs are known to regulate various immune systems, we hypothesized that human breast milk contains miRNAs that may be important for the development of the infant's immune system.

Findings: We profiled miRNA expression in human breast milk and detected high expression levels of immune-related miRNAs in the first 6 months of lactation. Furthermore, these miRNA molecules are stable even in very acidic conditions, indicating that breast milk allows dietary intake of miRNAs by infants.

Conclusions: Our findings provide new insight into how breast milk can modulate the development of the infant's immune system. This study suggests the transfer of genetic material as miRNA from human to human occurs by means other than through sexual reproduction.

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Figures

Figure 1

Expression profile of miRNAs in human breast milk. (a) RNA isolation from breast milk. RNA from breast milk was detected using a Bioanalyzer. The milk contains a substantial amount of small RNA (<300 nt), but very little or no ribosomal RNA (18S and 28S rRNA). (b--d) Expression profiling of miRNAs in human breast milk from miRNA microarray. (b) miRNAs in breast milk that were detected or hardly detected by microarray analysis. (c) Upper panel: a clustering analysis of the expression of breast milk miRNAs before and after the infants received complementary food. Samples 1, 2 and 3 were from different mothers. Breast milk samples were taken during the first 6 months after birth (0--6) and during the subsequent months (6+). Lower panel: Strongly expressed miRNA in breast milk before and after the infants received complementary food. (d) Correlation of gene expression signals between samples obtained from the same mother during the first 6 months and during the following 6 months are shown. The relationship between samples from different mothers was not as close.

Figure 2

Comparison by qRT-PCR of immune-related miRNAs in the breast milk obtained before 6 months of age (n = 5) (before the infants received complementary food) and from 6 to 12 months of age (n = 13) (when infants were receiving complementary food).

Figure 3

General characterization of miRNAs in breast milk. (a--c) The stability of breast milk miRNAs. Total RNA was extracted and then analyzed by qRT-PCR. Breast milk was (a) incubated with RNase A/T for 3 h at 37°C, (b) subjected to three freeze-thaw cycles or (c) treated for 3 h in a low pH solution (pH 1) before RNA extraction. Representative data are shown. (d) Expression of miR-181a and miR-17 derived from CD63-positive exosomes isolated from human breast milk (0.3 ml) from different mothers (n = 4). Human breast milk was immunoprecipitated with anti-CD63 antibody or isotype control.

Figure 4

Immune-related miRNA levels in human breast milk (n = 5) and serum (n = 6) of healthy subjects measured by qRT-PCR.

Figure 5

Exosome-like vesicles from human breast milk display the typical size (30--300 nm) and ultrastructure of electron-dense and electron-lucent microvesicles (arrows). miRNAs in the vesicles within breast milk are received by infants and facilitate many aspects of the infant's development. Scale bar, 100 nm.

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