Following a previous genome-wide association study (GWAS 1) including 744 cases and 895 controls, we analyzed genome-wide association data from a new cohort of Han Chinese (GWAS 2) with 1,510 polycystic ovary syndrome (PCOS) cases and 2,016 controls. We followed up significantly associated signals identified in the combined results of GWAS 1 and 2 in a total of 8,226 cases and 7,578 controls. In addition to confirming the three loci we previously reported, we identify eight new PCOS association signals at P < 5 × 10(-8): 9q22.32, 11q22.1, 12q13.2, 12q14.3, 16q12.1, 19p13.3, 20q13.2 and a second independent signal at 2p16.3 (the FSHR gene). These PCOS association signals show evidence of enrichment for candidate genes related to insulin signaling, sexual hormone function and type 2 diabetes (T2D). Other candidate genes were related to calcium signaling and endocytosis. Our findings provide new insight and direction for discovering the biological mechanisms of PCOS.
Extracellular vesicles (EVs) in milk harbor a variety of compounds, including lipids, proteins, noncoding RNAs, and mRNAs. Among the various classes of EVs, exosomes are of particular interest, because cargo sorting in exosomes is a regulated, nonrandom process and exosomes play essential roles in cell-to-cell communication. Encapsulation in exosomes confers protection against enzymatic and nonenzymatic degradation of cargos and provides a pathway for cellular uptake of cargos by endocytosis of exosomes. Compelling evidence suggests that exosomes in bovine milk are transported by intestinal cells, vascular endothelial cells, and macrophages in human and rodent cell cultures, and bovine-milk exosomes are delivered to peripheral tissues in mice. Evidence also suggests that cargos in bovine-milk exosomes, in particular RNAs, are delivered to circulating immune cells in humans. Some microRNAs and mRNAs in bovine-milk exosomes may regulate the expression of human genes and be translated into protein, respectively. Some exosome cargos are quantitatively minor in the diet compared with endogenous synthesis. However, noncanonical pathways have been identified through which low concentrations of dietary microRNAs may alter gene expression, such as the accumulation of exosomes in the immune cell microenvironment and the binding of microRNAs to Toll-like receptors. Phenotypes observed in infant-feeding studies include higher Mental Developmental Index, Psychomotor Development Index, and Preschool Language Scale-3 scores in breastfed infants than in those fed various formulas. In mice, supplementation with plant-derived MIR-2911 improved the antiviral response compared with controls. Porcine-milk exosomes promote the proliferation of intestinal cells in mice. This article discusses the above-mentioned advances in research concerning milk exosomes and their cargos in human nutrition. Implications for infant nutrition are emphasized, where permitted, but data in infants are limited.
Exosomes are natural nanoparticles that play an important role in cell-to-cell communication. Communication is achieved through the transfer of cargos, such as microRNAs, from donor to recipient cells and binding of exosomes to cell surface receptors. Exosomes and their cargos are also obtained from dietary sources, such as milk. Exosome and cell glycoproteins are crucial for intestinal uptake. A large fraction of milk exosomes accumulates in the brain, whereas the tissue distribution of microRNA cargos varies among distinct species of microRNA. The fraction of milk exosomes that escapes absorption elicits changes in microbial communities in the gut. Dietary depletion of exosomes and their cargos causes a loss of circulating microRNAs and elicits phenotypes such as loss of cognitive performance, increase in purine metabolites, loss of fecundity, and changes in the immune response. Milk exosomes meet the definition of bioactive food compounds.
A strategy is described for modular catalyst development based upon metal-directed self-assembly of bifunctional subunits around a structural metal to form a heteroleptic complex in which a second set of ligating groups are now suitably disposed to bind a second metal to form a catalytic site. A library of chiral diphosphites was prepared via metal-directed self-assembly and used in a simple asymmetric allylic amination, giving enantiomeric excesses as high as 97%.
Background Exosomes transfer regulatory microRNAs (miRs) from donor cells to recipient cells. Exosomes and miRs originate from both endogenous synthesis and dietary sources such as milk. MicroRNA (miR)-200a-3p is a negative regulator of the pro-inflammatory chemokine (C-X-C motif) ligand 9 (CXCL9). Male Mdr1a−/− mice spontaneously develop clinical signs of inflammatory bowel disease (IBD). Objectives We assessed whether dietary depletion of exosomes and miRs alters the severity of IBD in Mdr1a−/− mice due to aberrant regulation of pro-inflammatory cytokines. Methods Starting at 5 weeks of age, 16 male Mdr1a−/− mice were fed either milk exosome and RNA-sufficient (ERS) or milk exosome and RNA-depleted (ERD) diets. The ERD diet is characterized by a near-complete depletion of miRs and a 60% loss of exosome bioavailability compared to ERS. Mice were euthanized when their weight loss exceeded 15% of peak body weight. Severity of IBD was assessed by histopathological evaluation of cecum. Serum cytokine and chemokine concentrations and mRNA and miR tissue expression were analyzed by multiplex enzyme-linked immunosorbent assays, RNA-sequencing analysis and reverse transcriptase quantitative PCR, respectively. Results Stromal collapse, gland hyperplasia and additive microscopic disease scores were 56.7% ± 23.3%, 23.5% ± 11.8% and 29.6% ± 8.2% lower, respectively, in ceca of ERS mice compared to ERD mice (P < 0.05). The serum concentration of CXCL9 was 35.0% ± 31.0% lower in ERS mice compared to ERD mice (P < 0.05). Eighty-seven mRNAs were differentially expressed in the ceca from ERS and ERD mice; 16 of these mRNAs are implicated in immune function. The levels of four and one out of five miRs assessed (including miR-200a-3p) were up to 63% lower in livers and ceca, respectively, from ERD mice compared to ERS mice. Conclusions Milk exosome and miR depletion exacerbates cecal inflammation in Mdr1a−/− mice.
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