Abstract
Microbiota-derived short-chain fatty acids (SCFAs) and organic acids produced by the fermentation of non-digestible fibre can communicate from the microbiome to host tissues and modulate homeostasis in mammals. The microbiome has circadian rhythmicity and helps the host circadian clock function. We investigated the effect of SCFA or fibre-containing diets on circadian clock phase adjustment in mouse peripheral tissues (liver, kidney, and submandibular gland). Initially, caecal SCFA concentrations, particularly acetate and butyrate, induced significant day-night differences at high concentrations during the active period, which were correlated with lower caecal pH. By monitoring luciferase activity correlated with the clock gene Period2 in vivo, we found that oral administration of mixed SCFA (acetate, butyrate, and propionate) and an organic acid (lactate), or single administration of each SCFA or lactate for three days, caused phase changes in the peripheral clocks with stimulation timing dependency. However, this effect was not detected in cultured fibroblasts or cultured liver slices with SCFA applied to the culture medium, suggesting SCFA-induced indirect modulation of circadian clocks in vivo. Finally, cellobiose-containing diets facilitated SCFA production and refeeding-induced peripheral clock entrainment. SCFA oral gavage and prebiotic supplementation can facilitate peripheral clock adjustment, suggesting prebiotics as novel therapeutic candidates for misalignment.
Highlights
Revealed an interesting insight into the circadian clock
The concentration of butyrate used was higher (5 mM of butyrate in culture) than actual concentrations observed in vivo (~100 μM in peripheral tissue)[19,20], and it is still unclear whether Short-chain fatty acids (SCFAs) has an effect on the peripheral clock entrainment after oral injection of SCFA or dietary fibre intake
In order to elucidate the effect of SCFA production after intake of dietary fibre on the peripheral circadian clock, we investigated whether refeeding of dietary fibre-containing diets produced an increase in the entrainment speed of peripheral clocks to food intake patterns
Summary
Revealed an interesting insight into the circadian clock. There is day-night difference in composition, localization, or function of the intestinal microbiome, which is dependent on the host’s feeding cycle[13,14,15,16,17]. The concentration of butyrate used was higher (5 mM of butyrate in culture) than actual concentrations observed in vivo (~100 μM in peripheral tissue)[19,20], and it is still unclear whether SCFA has an effect on the peripheral clock entrainment after oral injection of SCFA or dietary fibre intake. We investigated the effect of orally gavaged SCFA and lactate on PER2::LUC rhythms[21] in peripheral tissues such as the liver, kidney, and submandibular gland of antibiotic-treated, microbiota-reduced mice, with different doses or timings of injection. We applied SCFA to mouse embryonic fibroblast (MEF) or cultured liver slices while monitoring PER2::LUC rhythms to determine a direct or indirect effect of SCFA to peripheral tissues. In order to elucidate the effect of SCFA production after intake of dietary fibre on the peripheral circadian clock, we investigated whether refeeding of dietary fibre-containing diets produced an increase in the entrainment speed of peripheral clocks to food intake patterns
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