ω3 polyunsaturated fatty acids (PUFAs) have anti-allergic and anti-inflammatory properties, but the immune-metabolic progression from dietary oil remains to be investigated. Here we identified 17,18-epoxyeicostetraenoic acid (17,18-EpETE) as an anti-allergic metabolite generated in the gut from dietary ω3 α-linolenic acid (ALA). Biochemical and imaging mass spectrometry analyses revealed increased ALA and its metabolites, especially eicosapentaenoic acid (EPA), in the intestines of mice receiving ALA-rich linseed oil (Lin-mice). In murine food allergy model, the decreased incidence of allergic diarrhea in Lin-mice was due to impairment of mast cell degranulation without affecting allergen-specific serum IgE. Liquid chromatography–tandem mass spectrometry-based mediator lipidomics identified 17,18-EpETE as a major ω3 EPA-derived metabolite generated from dietary ALA in the gut, and 17,18-EpETE exhibits anti-allergic function when administered in vivo. These findings suggest that metabolizing dietary ω3 PUFAs generates 17,18-EpETE, which is an endogenous anti-allergic metabolite and potentially is a therapeutic target to control intestinal allergies.
Bioenergetic metabolism varies during cell differentiation, but details of B cell metabolism remain unclear. Here, we show the metabolic changes during B cell differentiation in the intestine, where B cells differentiate into IgA(+) plasma cells (PCs). Naive B cells in the Peyer's patches (PPs) and IgA(+) PCs in the intestinal lamina propria (iLP) both used the tricarboxylic acid (TCA) cycle, but only IgA(+) PCs underwent glycolysis. These metabolic differences reflected their dependencies on vitamin B1, an essential cofactor for the TCA cycle. Indeed, the diminished activity of the TCA cycle after dietary vitamin B1 depletion decreased the number of naive B cells in PPs without affecting IgA(+) PCs in the iLP. The maintenance of naive B cells by dietary vitamin B1 was required to induce-but not maintain-intestinal IgA responses against oral antigens. These findings reveal the diet-mediated maintenance of B cell immunometabolism in organized and diffuse intestinal tissues.
The reconstitution reaction of ferric cyanomyoglobin from apomyoglobin and hemin dicyanide was investigated with a stopped-flow apparatus by the use of five kinds of probes; (a) Soret absorption, (b) fluorescence quenching of tryptophan, (c) far-ultraviolet CD, (d) near-ultraviolet CD, and (e) Soret CD.After mixing of apomyoglobulin with equimolar amounts of hemin dicyanide, the Soret absorption band was shifted to longer wavelengths within 10 ms. The shifted band kept its shape for a few seconds, and then gradually shifted to shorter wavelengths. A rate constant of the slow reaction was 1.1 x lo-' s-'. Time courses of fluorescence quenching followed a second-order reaction with a rate constant of 9 x lo7 M-' s-' . Far-ultraviolet CD recovered to the level of native state within the response time of an apparatus (= 64 ms). Near-ultraviolet CD and Soret CD changed with first-order rate constants of 5 -30 s-l and 5 x On the basis of the kinetic results we propose the following reconstitution pathway of myoglobin. Apomyoglobin has essentially a highly folded structure similar to myoglobin, but there are some differences in the secondary structure between them. In the first step, heme enters the pocket-like site of apomyoglobin and interacts with surrounding hydrophobic residues in the pocket, and then the interaction may give a complete ordered structure to the protein. Second, the tertiary structure of the heme pocket is partly constructed. Third, the iron-proximal His bond occurs, followed by the attainment of the final conformation. This sequence of the events shows that the polypeptide chain is entirely folded before the completion of three-dimensional structure of the heme pocket. The reconstitution pathway is fairly different from that of the CI subunit of hemoglobin reported by Leutzinger and Beychok [Proc. Natl Acad. Sci. USA (1981) 78, 780-7841, which described how a drastic recovery in helicity was observed on the heme-binding, and that the recovery is introduced by the formation of the heme pocket structure. The difference in the results found for the CI subunit and myoglobin suggests a difference in conformation: in apomyoglobin most of the helices are arranged and folded around a helix core to form a compact structure as a whole, while in apo-a-subunit some helices are not folded around the helix core. Helix D, which is absent in the a subunit, may play an important role in folding of the helices.
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